Scientific Tools for Conservation
IConservation
nfrared Spectrosco
y
in
p
Science
Michele
R.
Derrick
Dusan Stulik
James M. Landry
T h e G e t y Conservation I n s t i u t e
Los Angeles
Tevvy Ball, Managing Editor
Sylvia Tidwell, Copy Editor
Anita Keys, Production Coordinator
Hespenheide Design, Designer
Printed in the United States of America
10 9 8 7 6 5 4 3 2 1
©
1999 by the J. Paul Getty Trust
All rights reserved.
Illustration credits: Figures 3.8, 4.27, 4.28, 4.29, 5.16, 5.24, and 6.9: Courtesy
of the Journal of the American Institute for Conservation of Historic and Artistic
Works. Figures 4.20, 6.1, 6.2, 6.3, 6.10, 6.14, 6.15, 6.20, 6.21, 6.23, and 6.24:
From "Infrared Microspectroscopy in the Analysis of Cultural Artifacts," by
Michele R. Derrick, in Practical Guide to Infrared Microspectroscopy, ed.
Howard Humecki, pp. 287-322 (New York: Marcel Dekker, Inc., 1995).
Reproduced by permission.
The Getty Conservation Institute
The Getty Conservation Institute works internationally to further appreciation
and preservation of the world's cultural heritage for the enrichment and use of
present and future generations. The Institute is an operating program of the
J. Paul Getty Trust.
The Institute's Scientific Tools for Conservation series provides practical scientific
procedures and methodologies for the practice of conservation. The series is
specifically directed to conservation scientists, conservators, and technical experts
in related fields. Previously published in the series is Thin-Layer Chromatography
F.
Library of Congres Cataloging-in-Publication DaIta
for Binding Media Analysis (1996), by Mary
Striegel and Jo Hill.
Derrick, Michele R., 1955-
Infrared spectroscopy in conservation science
Michele R. Derrick, Dusan
Stulik, James M. Landry.
p.
cm.-(Scientific tools for conservation)
Includes bibliographical references and index.
ISBN 0-89236-469-6
1. Infrared spectroscopy.
I. Stulik, Dusan, 1956N8558.2.153D47
7021.8'8-dc21
2. Art-Expertising-Methodology Case studies.
II. Landry. James M.
III. Title.
IV. Series.
1999
99-37860
CIP
Contents
Chapter
Chapter
Chapter
1
2
3
vii
Foreword
ix
Preface
xi
Acknowledgments
13
44
68
112
11334
1156
12790
22341
256
History of Infrared Spectroscopy
Additional Reading
Infrared Absorption Theory
Electromagnetic Radiation
Wave Theory
Absorption Theory
Molecular Absorptions
Degrees of Freedom
Selection Rules
Group Frequencies
Infrared Spectra
Infrared Regions
Near-Infrared Region
Mid-Infrared Region
Far-Infrared Region
Summary
Additional Reading
Sample Collection and Preparation
Sampling Methodology
Sampling Design
Sampling Location
Sampling Implementation
Tools
Sample Documentation and Storage
Avoidance of Contamination
Sample Collection and Preparation Procedures
Gases
Liquids
Sampling with Swabs
Chapter
Chapter
4
5
238
42
44536
5520
66203
66598
77690
80
8822
88764
99321
5109
1120039
1122154
1297
Solids, Powders, and Particles
Fibers
Cross Sections
Summary
Additional Reading
Infrared Analysis Methods
Infrared Transmission Measurements
Infrared Window Materials
Transmission Analysis of Gases
Transmission Analysis of Liquids
Transmission Analysis of Solids
Infrared Reflection Measurements
Specular Reflection
Reflection-Absorption
Diffuse Reflection
Internal Reflection
Infrared Microspectroscopy
Microspectrophotometer Design
Microspectrophotometer Capabilities
Particle and Fiber Analysis
Cross Section Analysis
Microspectrophotometer Accessories
Summary
Additional Reading
Spectral Interpretation
Infrared Spectra
Absorption Bands
Plotting Format
Instrument Configuration
Qualitative Analysis
Spectral Quality
Visual Comparison
Computer Libraries
Spectral Region Examination
Spectra-Structure Correlations
Correlation Charts
Identification of Materials Used in Art and Art Conservation
Natural Organic Materials
Synthetic Resins (Polymers)
Colorants
Mixtures
Quantitative Analysis
Mathematical Manipulations of Spectra
Subtraction Techniques
Resolution Enhancement Methods
Summary
Additional Reading
Chapter
6
11330
4138
114418
51592
116731
117728
220015
220370
236
Case Studies
Identification and Characterization of Materials
Deterioration Studies
The Case Studies
Case Study
Case Study
Case Study
Case Study
Case Study
Case Study
Case Study
Case Study
Case Study
Case Study
132::
465:
798::
10
Ultramarine Pigments
Creosote Lac Resin
Chumash Indian Paints
Varnish on a Desk
Reflection versus Transmission
Painting Cross Sections
Vikane
Parylene
Cellulose Nitrate Sculptures
Dead Sea Scrolls
Summary
Appendix I: Selected Infrared Spectra Collections and
Digitized Libraries
Appendix II: Infrared Reference Spectra
Glossary
Suppliers
References
Index
About the Authors
Foreword
Since the founding of the conservation field's flagship j ournal, Studies in
Conservation, in the early 1 95 0s, the number of museum laboratories
has increased remarkably. Where once a single optical microscope may
have sat in dusty isolation, today chemists, engineers, physicists, and
other scientists make use of a wide range of analytical instruments, often
working side by side with conservators and curators. It is clear that those
who benefit from this development are people responsible for managing
and interpreting vast arrays of collection types, but the public is also a
prime recipient of this benefaction.
This relatively recent infusion of science into the museum
environment has significantly enhanced preservation practices, affording
a deepened understanding of materials' properties and degradation
processes. The simple optical microscope now coexists with many other
instruments, which allow advanced techniques for separation and chemi
cal identification, high magnification and analysis of microstructure, and
imaging using nuclear magnetic resonance, thermal neutrons, and a range
of electromagnetic radiation.
Today the most widely used method in most museum labora
tories is infrared (IR) spectroscopy. It is extremely cost-effective, and it
has directly contributed to the current enhanced interest in organic mate
rials in art and archaeology. Recent years have witnessed the develop
ment of a robust network of IR users, who share spectra and insights
on a regular basis. The activities of such a group, informal as it may be,
help to refine the method, broaden its utility, and provide a specialized
training environment for its novitiates. Many benefit from this-curators,
museum directors, collectors, and, of course, the museum-going public.
For all these reasons we are proud to include this volume as
the second to be published in the Getty Conservation Institute's
Scientific Tools for Conservation series, which is designed to present
methods and procedures of practical use to conservators, conservation
scientists, and others engaged in the preservation of the cultural heritage.
viii
Foreword
We are grateful to the authors, Michele R. Derrick, Dusan Stulik, and
James M. Landry, for their dedication in writing this book. With its
focus on the practical applications of IR spectroscopy-including a
detailed presentation of ten case studies-the present volume hopes to
make this important technology more readily available to those who
can benefit from it the most.
Tim Whalen
Director
The Getty Conservation Institute
Preface
The purchase and use of infrared ( IR) spectrometers in art conservation
labs have grown more than tenfold in the last decade. This expansion
can be traced to decreased instrument costs, enhanced interest in organic
materials in art and archaeological obj ects, and increased requests for
scientific analyses by conservators and curators. Additionally, the current
computer-driven, user-friendly IR instruments make it extremely easy to
perform an IR spectral analysis on a sample. But herein lies a problem,
since simplification of a method can result in lost intricacies and misin
formation. Thus, critical evaluation and availability of information on a
technique are important in order for pitfalls to be recognized and for any
of the technique's significant limitations to be understood.
This book fills a gap, since currently there is no available
compilation of information that deals directly with the IR analysis of
historical and artistic materials. These materials can pose significant
problems for analysts, as they tend to be natural products that are often
mixtures and are sometimes affected by age. Scientific books and refer
ence sources rarely provide key information necessary for dealing with
such materials.
This text provides practical information on the use of IR
spectroscopy for the analysis of museum obj ects, disseminating many
sample handling and spectral acquisition techniques specifically applica
ble to their analysis, along with discussions of these techniques' potential
problems. This book is meant to be a learning tool as well as an infor
mation resource. While the present volume provides a comprehensive
overview of the technique, individual chapters may be read indepen
dently for specific information.
Chapter 1 defines IR spectroscopy and provides a historical
2
perspective on its development as a modern analytical technique.
Chapter
provides an overview of the position and relation
ship of the IR spectral region to the entire electromagnetic spectrum. It
also supplies a simplified version of the theory of molecular interactions
that produce IR spectral patterns. Included is a basic description of the
phenomena that occur in a material to produce a unique IR spectrum.
Sample collection and preparation are key steps in the analy
sis of all materials. Chapter 3 provides basic and widely applicable infor
mation on sampling methodology and implementation. This chapter is
important not j ust for analysts but also for anyone who may be requesting,
x
Preface
collecting, or submitting samples for analysis. Emphasis is placed on the
effect of sampling on analytical results. Comparative tables are included
that illustrate the capabilities and sample requirements of some common
analytical techniques.
Once the sample is collected, several options exist for its IR
analysis. Chapter 4 reviews the theory and operation of both transmission
and reflectance methods, as well as provides references as to how each of
the techniques has been used in the analysis of art materials. Many excel
lent books that provide more detailed information about IR methods and
instrumentation are also included in an additional reading list.
Chapter 5 focuses on the spectral interpretation of conserva
tion and artist materials and provides schemes or flowcharts to facilitate
the characterization of unknowns. Examples of basic peak identification
for the maj or classifications of materials found in works of art are given.
Problems relating to material mixtures are discussed, as are several
options for the mathematical manipulation of spectra.
Chapter 6 incorporates reviews of existing conservation and
related literature. Case studies illustrate several types of problems and
materials and show approach, utility, and limitations of the techniques.
Professionals who are not spectroscopists may find individual sections
useful to their understanding of the applications and restrictions of the
different procedures.
One of the most important factors in IR spectral identifi
cation is access to reference spectra corresponding to appropriate materi
als. Appendix I is a list of commercial sources that supply digitized and
hard-copy spectral collections. Appendix II provides IR spectra of com
mon art and conservation materials. There is a list of references, and
additional readings on related subjects are provided at the end of each
chapter.
IR spectroscopy is a useful and fascinating challenge that can
provide the answers to many of the problems encountered in the analysis
of works of art. It is hoped that the practical information provided in
this book will stimulate interest in, and perhaps lay the groundwork for,
many future IR applications.
Michele R. Derrick
Acknowledgments
Funds for the preparation of this manuscript were provided in part by
a Kress Foundation conservation publication fellowship awarded to
Michele Derrick in 1 99 5 . Portions of this book were presented at a
workshop held j ointly by the Getty Conservation Institute ( GCI) and
Loyola Marymount University, Los Angeles, in 1 9 9 1 .
The authors would like t o thank the following organizations and people for providing samples for analysis: the J. Paul Getty
Museum, Los Angeles (Andrea Rothe and Brian Considine ) ; the Museum
of Modern Art, New York ( Eugena Ordonez and Patricia Houlihan) ; the
Fine Arts Museum, Houston ( Christopher Shelton); the Bureau of Land
Management, Needles, California (Tom Holcomb and Claire Dean) ; and
the Museum of Natural History, New York ( David Thomas) . The authors
would also like to thank Miguel Angel Corzo, the former director of
the GCI, for his support of the book; Neville Agnew for initiating this
series of books; Kevin Thompson for providing several historic books
on optics; Eric Hansen, Richard Newman, and Charles Selwitz for their
helpful suggestions; Janice Carlson for her extensive and meticulous tech
nical editing; Tanya Kieslich and Margaret Bolton for preparing some of
the drawings in Chapter 4; Herant Khanj ian for photographs in Chapter
4; and the GCI Information Center for obtaining numerous and often
obscure offprints.
Additionally, Michele Derrick gives her deepest appreciation
and gratitude to her family, John, Erin, and Kristin Stacy, for their
patience during the lengthy period of manuscript writing and rewriting.
Chapter
1
History of Infrared Spectroscopy
In simplified terms, one dictionary defines infrared as "those invisible
rays just beyond the red end of the visible spectrum . . . [that] have a
penetrating heating effect: used in cooking, photography, etc . " ( Guralnik
1 9 8 4 ) . While this may seem obvious, since infrared (IR) is such an inte
gral part of our lives, it was not until 1 8 00 that IR was recognized as a
distinct region of the energy spectrum. This discovery was made by Sir
William Herschel, an astronomer, when he measured the heating effect
of sunlight (Herschel 1 8 0 0 ) . However, the field of IR spectroscopy-i .e.,
the study of wavelengths of light in the IR region of the spectrum and
their interaction with various materials-did not develop at that time
due to difficulties in building suitable detectors to measure IR radiation.
Eventually, beginning in 1 903, William W. Coblentz conducted compre
hensive experiments leading to the accurate measurement of IR spectra
for hundreds of inorganic and organic compounds ( Coblentz 1 90 5 ) .
Interest increased i n the potential o f I R spectroscopy for analytical chem
istry when the first prototypes of IR spectrometers were built in the
1 930s. Commercial development of IR spectrometers quickly followed,
stimulated by the need for rapid analytical methods in the synthetic rub
ber industry. This development expanded the acquisition of IR spectra
and motivated research into deeper theoretical studies of all features of
IR spectra. The next j ump came as advances in electronics during and
after World War II furnished the thermocouple detector technology that
led to development of stable double beam spectrophotometers (Wright
and Hersher 1 947). By the 1 95 Os, IR spectroscopy was established as a
key analytical method in academic and industrial labs.
Most IR instrumentation used through the 1 970s was based
on prism or grating monochromators. A maj or breakthrough in IR
technology was the introduction of Fourier transform infrared ( FT-IR)
spectrometers. In the late 1 8 00s, Albert Michelson developed the inter
ferometer for studying the speed of light ( Michelson 1 8 9 1 ) . Two years
later, Lord Rayleigh recognized that the output from an interferometer
could be converted to a spectrum by a mathematical procedure devel
oped about seventy years earlier by the French mathematician Fourier
( Rayleigh 1 8 9 1 ) . However, because of the numerical complexities of the
Fourier procedure, it was not until 1 949 that Peter Fellgett actually cal
culated a spectrum from an interferogram ( Fellgett 1 970). Fellgett, an
astronomer, used Fourier transform spectroscopy to isolate the weak
2
Chapter
1
signals of distant stars from environmental background noise and in
doing so discovered the multiplex advantage, later named in his honor. A
few years later, Jacquinot, a French scientist, pointed out the throughput
advantage of interferometry (Jacquinot 1 95 4 ) . These advantages for
FT-IR over dispersive instruments translated into practical improvements
such as high-speed data collection, increased resolution, lower detection
limits, and greater energy throughput.
Acceptance of FT-IR spectroscopy, however, was slowed by
the complexity of the calculations required to transform an interferogram
into a spectrum. Then, in 1 964, the discovery of the fast Fourier trans
form ( FFT) algorithm by James Cooley and John Tukey reduced the time
for the computer calculation of the transform from hours to j ust a few
seconds ( Cooley and Tukey 1 96 5 ) . Even so, it was still a time-consuming
process for spectroscopists to record an interferogram on a paper tape
or punched cards, walk it over to the computing center and wait for
calculation of the spectrum ( Griffiths and de Haseth 1 9 8 6 ) . The next
significant change came in 1 9 69, when the first commercial FT-IR with
a dedicated minicomputer was developed and sold by Digilab (see
Suppliers). For the first time, spectroscopists were able to see a spectrum
plotted shortly after the interferogram was collected; correspondingly, it
took less total time to obtain a spectrum using an FT-IR spectrometer
than using a dispersive instrument. Since then, further developments in
computer technology, together with substantial price decreases, have
been responsible for the large number of commercial FT-IR spectrometers
on the market and for the wide application of FT-IR spectroscopy in all
branches of science and technology.
Particularly useful for the field of art conservation was the
coupling of the optical microscope with the IR spectrometer. Initial stud
ies were done at Oxford by Barer, Cole, and Thompson, who used a
microscope designed with all-reflecting optics attached to a dispersive IR
spectrometer ( Barer, Cole, and Thompson 1 94 9 ) . Although the system
performed well, the sensitivity achievable by a microscope in combina
tion with a wavelength dispersive IR spectrometer was low, and interest
in the technique waned. Revival of IR micro spectroscopy was stimulated
by the development of FT-IR instrumentation, with its increased energy
throughput. In 1 9 8 1 , at McCrone Associates, Robert Z. Muggli success
fully adapted a microscope to an FT-IR spectrometer ( Palenik 1 992 ) .
In 1 9 8 3 Digilab introduced the first commercial microscope designed
specifically for FT-IR spectrometers by Spectra-Tech (see Suppliers).
Following that time, a number of other instrument companies have
developed IR microspectrophotometers and micro accessories for IR
spectrometers. Availability of the IR microscopes precipitated a new
range of analytical applications, and IR microspectroscopy has become
a powerful tool in many branches of basic and applied research.
The historical background for IR spectroscopy is shown
in Figure 1 . 1 .
3
History of I nfrared Spectroscopy
1 700s-Fourier
developed mathematical
1 80G-Herschel discovered
transform (FT) method.
IR radiation .
•
•
+
1 905--Coblentz's
1 891 -Michelson
experiments led to IR
published design of
spectra of organic and
his interferometer.
inorganic compounds .
.
1 930s-lnterest increased
in IR application to
1 949-Fellgett
analytical chemistry.
discovered multiplexing
advantage of FT.
•4-J
t5--C
1 947-Wright and Hersher
developed double beam
1 95
dispersive IR
discovered throughput
spectrophotometer.
advantage of FT.
•
\
1 949-Barer and coworkers
linked IR spectrometer
1 96
1 969-Digilab
with microscope.
commercial FT-IR
acquinot
ooley and Tukey
discovered fast Fourier
�
transform (FFT) algorithm.
with dedicated
minicomputer.
T
1 983-Spectra-Tech and
Digilab developed the first
commercial FT-IR
Figure 1 . 1
microspectrophotometer.
f-+
1 980s-FT-IR combined with
personal computers to make
widely used, versatile, and cost-
Sign ificant events leading to the
effective method of analysis.
development of cu rrent FT-IR spec
high-quality microanalysis.
Microspectrophotometers provide
trometers and m icrospectrometers.
Additional Reading
Colthup, N. B . , L. H. Daly, and S. E. Wiberly
1990. Introduction to Infrared and Raman Spectroscopy. 3d ed. Boston:
Academic Press.
Griffiths, P. A., and J . A. de Haseth
1986. Fourier Transform Infrared Spectrometry. New York: Wiley-Interscience.
S i lverstein, R. M . , F. C. Bassler, and T_ C. Morri l l
1981. Spectrometric Identification of Organic Compounds. 4th ed. New York: John
Wiley and Sons.
S m ith, A. L.
1979. Applied Infrared Spectroscopy: Fundamentals, Techniques, and Analytical
Problem Solving. Chemical Analysis series, vol. 54. New York: John Wiley and Sons.
Chapter
2
Infrared Absorption Theory
Electromagnetic Radiation
In simplest terms, spectroscopy is defined as the interaction of light with
matter. Light, in this context, is the broad spectrum of continuous energy
called the electromagnetic spectrum. The maj or regions of the electro
magnetic spectrum are shown in Figure 2 . 1 . There is no uniform naming
system for the spectral regions, as the specific names for each type of
radiation-such as visible, X ray, and radio-were assigned when it was
discovered. Even so, the designations are commonly known and useful
for quick orientation. The same physical properties govern all radiation,
regardless of its spectral region.
The types of radiation are generally grouped by the kinds of
chemical and physical effects they can produce on matter. For example,
in a magnetic field, exposure to the low-energy radio frequency radia
tion only reorients nuclei, while exposure to the slightly higher-energy
microwave region changes electron spin states of molecules with unpaired
electrons. Microwave radiation can also change the rotational energy of
molecules; this effect is used to heat food quickly in a microwave oven.
In the middle regions of the electromagnetic spectrum, absorption of IR
radiation causes changes in the vibrational energy of molecules. Visible
(Vis) and ultraviolet (UV) radiations alter the electron energies of loosely
held outer electrons of atoms and molecules. Higher-energy X rays can
cause electron transitions between inner electron levels, and gamma radi
ation produces changes within atomic nuclei. As all compounds absorb
radiation in multiple regions of the spectrum, the information on molecu
lar activity in each region provides complementary data for material
characterization.
The following overview of the relationship of radiant energy
to its effects on matter has a focus on IR absorption theory. For more
information, several excellent references are listed at the end of the chap
ter. In particular, the book by Colthup, Daly, and Wiberley ( 1 990) pro
vides good, in-depth coverage of IR theory and molecular structure
correlations.
Wave theory
All energies of the electromagnetic spectrum can be considered to be
waves that move at the speed of light, with the types of radiation differ-
5
I nfrared Absorption Theory
O-H
40.-..360.- 32-0 -28lilt0.. 2.4.,0 20 180 ,. 160 ...140.. ..120 ....10 ... 80 ...-60
FAR-IR
•WAEVNERUGMYBINECRINECARSEASE
I 1 X <(/)CDrm
IIIIIII
WAEVNELRNGYTDHECINREASE
A,
" 111
'
'-
20
Wavenumber (cm- 1 )
Wavenumber (cm-1)
I
GAMMA RAYS
RAYS
I
I
I
I
MICROWAVE
INFRARED (IR)
ULTRAVIOLET (UV)
I
I
I
Wavelength (f..lm)
Figure 2 . 1
II
III
v,
I
RADAR, RADIO,
TELEVISION
WAVES
ing only in amplitude, frequency, and wavelength ( Fig. 2 . 2 ) . The ampli
Spectral regions of electromagnetic
tude is the height, or maximum size, of the wave, which corresponds to
rad iation, with expansion of IR region .
the intensity, or volume, of the signal. The frequency,
is the number
of oscillations, or waves, per unit time-that is, cycles per second. The
wavelength,
is the distance between two successive maxima or minima
of a wave-that is, the length of one wave. The wavelength of the radia
tion is inversely proportional to frequency. Thus, high-frequency radia
tion has short wavelengths.
Energy, according to Planck's law, is directly proportional
to frequency. Since frequency is inversely proportional to wavelength, it
follows that energy of electromagnetic radiation and wavelength are also
inversely related. Thus, longer wavelengths have lower energy and fre
quency, while shorter wavelengths have higher energy.
Electromagnetic radiation can also be characterized by the
number of waves per unit length. This is termed wavenumber,
v
1
A
v:
Chapter 2
6
A.
(wavelength)
A
"0:Ci«�OJE
v = 1.5
z A.
I
·
1
Bv =
z
vx = v = =
y
Figure 2 . 2
Two frequencies o f electromagnetic waves
at a
1
second interval. Radiation waves
can be characterized by their amplitude
(height), wavelength (distance between
two maxima), and frequency ( n u m ber of
oscillations per u nit ti me).
(wavelength)
OJ
"0
.Ci«€E
4
where:
uum (3
/ c (cm- 1 )
frequency ( Hz, sec- 1 ) / velocity of light in vac
1 01 0 cm/sec ) ; and A
wavelength (cm). While wavenumber is
usually expressed in cm units [ ( 1 /A cm- 1 ] , it could be expressed in any
reciprocal distance units. Because of the simple inverse relationship,
wavenumbers can readily be converted to wavelength units when needed.
For example, 1 000 wavenumbers (cm - 1 ) is the same as the wavelengths
of 0.001 cm or 0 . 0 1 I-Lm or 1 0 nm.
Frequency and wavenumber units have two advantages over
wavelength units. The first is that they remain constant, regardless of
the media traversed by the radiation, whereas the wavelength is reduced
when radiation passes through a medium with a refractive index greater
than that of a vacuum. This change in wavelength due to refractive index
is ignored except for high-accuracy experiments, since the refractive
index of air is near unity under normal conditions. The second advantage
of the use of frequency and wavenumber units over wavelength is that
they are directly proportional to energy. Thus, a transition that requires
greater energy will occur at a higher wavenumber. For this reason, wave
number units are commonly used in IR spectroscopy, as opposed to
wavelength units (i.e., nanometers or micrometers ) , which are commonly
used in visible and UV spectroscopy.
Absorption Theory
Toward the end of the nineteenth century, it became increasingly evident
that the classical laws of physics describing natural phenomena-such as
time, gravity, and momentum-did not successfully account for effects
7
Infrared Absorption Theory
observed when light interacted with matter. At the 1 904 St. Louis
World's Fair, top scientists debated for and against the existence of
atoms. Two years later, modern atomic theory was established when
experiments by Ernest Rutherford showed that atoms existed and that
each consisted of a positively charged nucleus surrounded by a cloud of
negatively charged electrons.
Experimentally, the emission spectrum of hydrogen consists
of a number of very sharp lines at distinct energies. In order to explain
the fact that the hydrogen atom emits only these characteristic frequen
cies, Niels Bohr postulated in 1 9 1 3 that the electrons of an atom occupy
specific energy states or levels that are defined by the radius of the orbit
of the electron around the nucleus. He further suggested that to move
between different energy states, atoms must absorb or emit energy and
that the amount of energy absorbed or emitted must be equal to the
difference in energy between the two levels ( Fig. 2 . 3 ) . One photon of
energy, hv, is emitted when an electron falls from a higher ( Eh) to a
lower ( El) energy state. This is also called the energy of transition, �E.
Alternatively, the electron can absorb a photon of light ( energy) and
move from a lower to a higher energy state.
Each element ( hydrogen, helium, etc . ) has electrons at unique
energy levels corresponding to its atomic structure. Even though an ele
ment is exposed to radiation of all wavelengths, only the wavelengths
( energy photons) that match the levels ( energy states) within that atom
can interact. The resultant pattern of energy lines, called a spectrum,
coincides with the absorption or emission of the photons specific to that
particular element. This phenomenon is responsible for the emission lines
produced by excited atoms and molecules, as well as for the absorption
bands in all regions of the electromagnetic spectrum. It forms the basis
for all atomic and molecular spectroscopy.
Nucleus
-1-+--,
Higher energy level (E h l
Lower energy level (E l l
Figure 2 . 3
B o h r atomic model f o r hydrogen. B o h r
hv
hv
theorized that energy whose frequency
matches the energy difference between
-
electronic levels can be absorbed or emit
ted as the electron transitions between the
two levels (hv
=
one photon) .
---....-.
Absorption
EI
---....I..--Emission
EI
8
Chapter 2
Molecular absorptions
Scientists expanded and advanced Bohr's theories to include multielectron
atoms and molecules. By the end of the 1 930s, detailed models were in
place that accounted for the placement of electrons in orbitals. These pro
vided key links to understanding elemental bonding, molecular structures,
and chemical reactions; this new knowledge in turn led to a greater
understanding of molecular spectroscopy.
Specific wavelengths of energy correspond to all molecular
transitions or motions: electronic, translational, rotational, and vibra
tional. In electronic motion, the electrons change energy levels or direc
tions of spin. For translational motion, the entire molecule shifts to a
new position, while for rotational motion, the molecule rotates around
its center of mass. Vibrational energy is required for individual atoms
within a molecule to change position relative to one another without
moving or rotating the molecule.
The energy of IR radiation is too low to affect the electrons
within an atom. IR radiation does, however, correspond to the energy
required for translational, rotational, and vibrational energy transitions.
Since a molecule's movements are unique to its structure, the measure
ment of these transitions makes IR a powerful tool for compound
characterization.
The primary transitions in the IR region are vibrational.
Rotational and translational transitions are weak and often difficult to
measure in the IR region without the aid of high-resolution instruments .
One common exception is for water vapor (regions 4000-3 600 and
1 8 00-1400 em- I ) , where the unrestricted motion of some gas-phase mol
ecules produces sharp rotational absorption bands that can easily be seen
( Fig. 2 . 4 ) . The occurrence of many unresolvable rotational transitions in
the IR region is one reason that a single, associated vibrational transition
appears as an absorption envelope or band rather than a sharp line, as
predicted by theory. Figure 2.5 illustrates the relationship of the vibra
tional energy levels to rotational energy levels.
Degrees of freedom
In a molecule, the atoms are constrained by molecular bonds to move
together in certain specified ways, called degrees of freedom. When a
particular molecular structure is known, its constraints allow prediction
of expected molecular transitions.
To determine the degrees of freedom for any molecule, first
consider the molecule positioned in a three-dimensional Cartesian coordi
nate system (x, y, and z ) , with its center at the point of origin (0, 0, 0 ) .
Then designate each atom b y its coordinates i n space (i.e., atom 1
x '
l
Y ' z )· For a molecule with N ( any number) atoms, the total number of
l l
coordinates (xn, y n' zn) specified will be 3N. These 3N coordinates are
=
the maximum number of potential transitions possessed by that molecule
and are called its degrees of freedom. For example, a molecule with
5 atoms has 15 degrees of freedom.
The 3N degrees of freedom can be assigned to the transla
tional, rotational, and vibrational motions of the molecule ( see Table 2 . 1
9
I nfrared Absorption Theory
---Water- vapor
(rotational motion)
...
..___ Liquid water
'"::u
(vibrational motion)
E
(/)
c
'"
c
'"
�
"*
Figure 2 .4
IR spectrum of water vapor rotational
absorption bands versus a spectrum of
the major vibrational absorption band for
liquid water.
3200
3600
4000
and Fig. 2 . 6 ) . All molecules have three translational degrees of freedom
that is, the center of mass of the molecule can move in three directions
(x, y, and z ) . If the molecule is nonlinear, then it also has three rotational
degrees of freedom as it spins around each of the three axes (x, y, and z ) .
Linear molecules have only two rotational degrees of freedom, since two
rotation directions are equivalent. Thus, the total of translational and
- 6,
-5
rotational degrees of freedom is 6 ( 5 for linear molecules ) . All remaining
motions, 3N
are vibrational degrees of freedom (3N
�
Figure 2.5
Vibrational
I evels
Energy transition levels for vibrational and
rotational transitions. Vibrational transi
tions produce the primary IR absorption
First excited state
bands. A fundamental transition occurs
when the absorbed photon increases the
energy level from the ground state (E o) to
the first excited state (E ) . An overtone
1
occurs when the transition covers two
transition levels. The very small energy dif
ference between rotational levels results in
very sharp. closely spaced rotational bands
in a spectru m .
in the case
E
�
�E = hv
Ground state
}
1
Eo
c
:;:;gE","'.:§·0w'"'':;:.'
LL:::J;Q>
-
c
.
c-
"0 '"
c�
c
0"'cu·£;w
0>�"'2-:;.0["
:;::;
c
t0·w
!9LL"'Eeg!0�
c
:;::;
_c
c�
-
"0:;::;
c '"
:::l�
Rotational
levels
OlWa;>
c
Chapter 2
10
Table 2 . 1
Degrees o f freedom corresponding t o type
of motion for any molecule with N atoms.
The total nu mber of degrees of freedom
for any molecule is 3 N .
Motion
Degrees of freedom
Translation (position of the molecule)
3
3 (nonli near)
(li near)
Rotation (about the center of the molecule)
2
3N
3N
Vibration
- 6 (nonli near)
- 5 (li near)
of linear molecules}. This is an important number, since vibrational tran
sitions are the strongest and most important in IR spectroscopy. For
x =
-
example, a nonlinear molecule with 3 atoms, such as S0 2' will have 3
fundamental vibrations [ ( 3
-6
-5
3)
6
3 ] , as shown in Figure 2 . 6 . All
vibrational motions of the atoms can be described completely in terms of
these 3N
or 3N
fundamental vibrations, which are called the nor
mal modes of vibration for the molecule.
The most common vibrations are stretching, torsional, and
bending modes. A stretching vibration increases or decreases the length
of the bonds between the atoms. A torsional, or skeletal, vibration
Ground state
Translational motion
Rotational motion
Figure 2 . 6
Degrees of freedom for molecular motion
of a triatomic molecule such as
502'
The
molecule at rest is shown at the top. The
molecule can move i n three translational
motions (x ,y, and z), as well as rotate
around the three axes. Of the nine total
motions allowed by the degrees of freedom
for a triatomic molecule, only three are left
for vibrational motion. These are shown as
stretching and bending vibrations.
Vibrational motion
y
Infrared Absorption Theory
11
involves the twisting of the backbone of the molecule. A bending vibra
tion changes the bond angles of the atoms relative to one another or
to the remainder of the molecule. Bending vibrations can be further
classified as scissoring, rocking, wagging, and twisting. Vibrations are
also characterized by their symmetry-that is, they can be symmetric or
asymmetric.
Selection rules
The degrees of freedom specify the maximum number of fundamental
vibrations for a molecule. A fundamental vibration-also called a first
order vibration-corresponds to a change from the molecular ground
state to the first energy level. A first-order vibration produces the
strongest energy absorptions, but only those that are active in the IR
region will be seen as an absorption band in the IR spectrum. Selection
rules, based on the symmetry of the molecule, determine whether a given
vibration will be seen in the spectrum. The primary selection rule, or
requirement, for active IR absorptions is that the vibration must change
the dipole moment of the molecule. In a heteronuclear molecule, non
symmetrical vibrations change the distance between the two nuclei and
thus its dipole moment. This vibrating dipole moment creates a dipolar
electric field that in turn absorbs a discrete unit of energy unique to that
transition. Vibrations in a homonuclear diatomic molecule or symmetri
cal vibrations in a heteronuclear molecule do not change the dipole
moment and thus are not seen in the IR spectrum.
In practice, the number of absorption bands observed in an
IR spectrum is usually smaller than the number of fundamental frequen
cies. In addition to the primary selection rule, other factors affecting a
reduction in the number of absorption bands are ( 1 ) degeneracy, where
two vibrational modes may occur at identical frequencies, (2) overlap
ping or weak absorptions, or ( 3 ) vibrational modes outside the instru
ment analysis range.
Alternatively, the number of observed bands may be increased
by the detection of weak, or so-called forbidden, absorptions, in which
the change in the vibrational level is greater than one. These are known
as overtones. Two or more fundamental vibrations may also interact to
produce discrete absorption bands that occur at a frequency correspond
ing to the sum or the difference of the individual band frequencies. Such
absorptions are known as combination bands.
Group frequencies
Within any molecule, a given functional group (a combination of atoms
such as a carbonyl group or an amide group) is responsible for IR absorp
tions at or near the same frequency, regardless of the rest of the molecule.
The position (i.e., frequency or wavenumber) of an absorption band
depends on the mass of the atoms in the absorbing group, along with the
strength and angles of the connecting bonds. A mathematical equation for
the vibrational frequency of a two-body system ( Hooke's law) can be used
to predict the absorption band position for simple molecules ( Smith 1 979).
However, only a limited number of small molecules have vibrational
12
Chapter
2
spectra simple enough for complete theoretical analysis and interpretation.
The maj ority of IR spectra-structure correlations are empirical, having
been determined by the analysis of a large number of compounds.
The vibrational frequencies for any particular functional
group are characteristic of that group-e .g., most carbonyl stretches
occur between 1 650 and 1 750 cm- l , and most carbon-hydrogen stretches
occur near 3000 cm
-1.
These characteristic vibrations are termed group
frequencies and are used for the identification of materials and for the
determination of structure in an unknown pure compound ( see Chap. 5
on spectral interpretation).
Molecules rarely consist of j ust a two-atom pair but, rather,
consist of multiple groups of atoms, each involved in its own vibrational
transitions. The energy of a vibration and, thus, the position of the band
in the IR spectrum are sometimes influenced by the atoms surrounding
the vibrational group. A highly electronegative atom (e.g., chlorine) near
a functional group can cause shifts in the electron distribution ( inductive
effects) that raise the frequency (wavenumber) of vibration. The presence
of heavier atoms near a functional group (e.g., nitrogen next to carbonyl
in an amide group) will dampen the oscillations (resonance ) and lower
the frequency (wavenumber) of vibration. Strong coupling between
stretching vibrations occurs only when there is an atom common to the
two vibrations. Interaction between bending vibrations requires a com
mon bond between the vibrating groups. Little or no interaction is
observed between groups separated by two or more bonds.
Infrared Spectra
Figure 2 . 7
I R spectrum of gelatin plotted a s percent
An IR spectrum displays detector response as percent transmittance ( % T)
transm ittance (% T) on the y-axis, and I R
on the y-axis, and IR frequency in terms of wavenumber (cm- 1 ) on the
frequency in terms o f wavenu mber (cm - ' )
x-axis, as shown in Figure 2.7. The detector response indicates the extent
on t h e x-axis.
of interaction of the IR electromagnetic radiation with the sample as it is
4000
3600
3200
2800
2400
2000
1 800
1 600
Wavenumber (cm- ' )
1 400
1 200
1 000
800
600
400
13
Infrared Absorption Theory
proportional to the resultant intensity of IR radiation that reaches the
detector after passing through the sample.
Two types o f interactions-absorption and transmission-are
important in the typical IR experiment. When the molecule in the sample
compartment of the spectrometer is exposed to a source of continuous IR
radiation, the photons of discrete energy units that are absorbed by the
molecule do not reach the detector. The IR spectrum reveals these miss
ing photons, or absorptions, as a series of well-defined, characteristic,
and reproducible absorption bands. Photons that are not absorbed by the
sample are transmitted to the detector essentially unaltered.
For a given wavelength or frequency of IR radiation striking
a sample, these two interactions are inversely related through the follow
ing equation:
A
where: A
=
absorbance and T
==
log liT
transmittance (% T/l 00 ) .
Infrared Regions
As was seen in Figure 2 . 1 , the IR spectral region of the electromagnetic
spectrum extends from the red end of the visible spectrum to the
microwave region; it includes radiation with wavenumbers ranging from
about 1 4,000 to 20 cm- I , or wavelengths from 0.7 to 500 /-Lm. Because
of application and instrumentation reasons, it is convenient to divide the
IR region into the near (NIR ) , middle ( IR or mid-IR) , and far ( FIR) sub
regions. The majority of analytical applications are found in the middle
region, extending from 4000 to 500 cm- 1 (2.5 to 20 /-Lm) .
Near-infrared region
The near-IR (NIR, NIRS) region extends from the visible region at
1 4 ,000 cm- 1 ( 0 . 7 /-Lm) to the mid-IR region at 4000 cm-1 ( 2 . 5 /-Lm) .
Because i t i s accessible with quartz optics, near-IR instrumentation is
often combined with UV-Vis spectrometers (UV-Vis-NIR). Spectra gener
ated in the near-IR region consist of many overtones and combinations
of the mid-IR region fundamental vibration modes. Since all organic
species absorb in the NIR and produce many overlapping bands, single
band spectroscopy and qualitative band assignments are nearly impos
sible. NIR is useful for quantitative work, including in situ monitoring
of reactions.
Mid-infrared region
The spectral range of greatest use for chemical analysis is the mid-IR
(MIR) region. It covers the frequency range from 4000 to 500 cm-1
(2.5-20 /-Lm ) . This region can be subdivided into the group frequency
region, 4000- 1 300 cm - 1 (2.5- 8 . 0 /-Lm) and the fingerprint region,
1 3 00-500 cm- 1 ( 8 . 0-20 /-Lm) .
14
Chapter
2
In the group frequency region, the main absorption bands
may be assigned to vibrational modes corresponding to individual func
tional groups:
NH-OH (4000-3000 cm- I )
C-H stretch region ( 3 000-2 800 cm- I )
window region (2800- 1 800 cm- I )
carbonyl region ( 1 800-1 5 00 cm- I )
Both the presence and absence o f these characteristic group frequency
bands are useful for characterizing molecular structure.
The absorption bands in the fingerprint region of the spec
trum are the results of single-bond as well as skeletal vibrations of poly
atomic systems. Multiple absorptions in this region make it difficult to
assign individual bands, but the overall combined pattern is very charac
teristic, reproducible, and useful for material identification when it is
matched to reference spectra.
Far-infrared region
The far-IR ( FIR) region is generally designated as 5 00-20 cm-I
(20-500 /-Lm) . In this region, the entire molecule is involved in low
frequency bending and torsional motions, such as lattice vibrations in
crystals. These molecular vibrations are particularly sensitive to changes
in the overall structure of the molecule that are difficult to detect in the
mid-IR region. For example, the far-IR bands of isomers and long-chain
fatty acids can often be differentiated in solid-state materials. FIR is also
useful in the identification and differentiation of many minerals and
colorants.
Summary
Light and matter can interact. The examination of this interaction is
termed spectroscopy. The interactions are characterized by the energy of
the radiation and its effects on materials. IR radiation supplies sufficient
energy to produce translational, rotational, and vibrational motion in
molecules. The measurement of the characteristic IR energies (photons)
that correspond to these transitions results in a spectrum. Based on its
atomic structure, each molecule produces a unique and characteristic IR
spectrum. The specific number and position of absorption bands for any
molecule are governed by its degrees of freedom, its functional groups,
and the IR selection rules. A spectral pattern, sometimes called a finger
print, is used to identify an unknown material when the absorptions in
its spectrum are matched with the absorptions in the spectrum of a
known material. Additionally, since functional groups (combinations of
atoms) produce absorptions at or near the same frequency, regardless of
the rest of the molecule, the presence or absence of certain functional
groups can be determined by interpretation of the IR spectrum.
Infrared Absorption Theory
15
Additional Reading
B ri l l , T. B .
1 98 0 . Light: Its Interaction with Art and Antiquities. New York: Plenum Press.
Colthup, N. B . , L. H. Daly, and S. E. Wiberley
1 990. Introduction to Infrared and Raman Spectroscopy. 3d ed. Boston:
Academic Press.
Schutte, C. J. H .
1 976. The Theory of Molecular Spectroscopy. Vol. 1. New York: Elsevier.
Si lverste i n , R. M . , F. C. Bassl er, and T. C. Morri l l
1 9 9 1 . Spectrometric Identification o f Organic Compounds. 5th ed. New York: John
Wiley and Sons.
S m ith, A. L.
1979. Applied Infrared Spectroscopy: Fundamentals, Techniques and Analytical
Problem Solving. Chemical Analysis series, vol. 54. New York: John Wiley and Sons.
Chapter
3
Sample Col lection and Preparation
Much effort has been put forth to optimize instrumentation for material
analysis, as well as to maximize the amount of information that can be
gleaned from data. The most important step of any analysis, however, is
the collection and preparation of a sample. Although numerous software
manipulations can sometimes recover useful data from an ill-prepared
sample, it is best to concentrate on using good sample handling and
experimental technique. The extra time required will be rewarded by
the generation of high-quality data. This chapter details collection and
preparation procedures for many types of samples.
Sampling Methodology
Sampling is defined as the process of selecting and collecting the sample
for analysis. Analytical chemists receive training in the importance of
correct sampling and valid data treatment. For example, Majors states,
" Collect the wrong sample, or collect the right sample incorrectly, and you
trivialize all that follows, rendering your data worthless" (Majors 1 992).
In the ideal situation, the analyst will be involved in and pre
sent at each sampling step. When this is not practical, the sampler should
provide as much information as possible to the analyst. In the analysis of
art obj ects, conservators are often the most qualified to remove samples
because of their skill and knowledge of the history, problems, and obj ec
tives related to the sampling. When sampling and analysis functions are
shared between more than one person, it is important to keep communi
cation open . A sampling strategy should be established, based on thor
ough discussion of analytical questions and experimental choices.
When dealing with works of art, the possibility for sampling
may be limited; thus, it is important to draft the sampling strategy
accordingly ( Reedy and Reedy 1 9 8 8 ) . Sampling consists of two steps:
first, the sampling design and, second, the implementation. The purpose
of the sampling design step is to determine how to obtain a representa
tive sample or set of samples related directly to the analysis question.
The second sampling step, implementation, involves the actual removal
and preparation of the sample or samples, with the goals of avoiding
sample loss and contamination.
17
Sample Collection and Preparation
Sampling design
The design, or planning, step requires intimate knowledge of the obj ect
as well as of the reason for analysis. Since cultural obj ects are irreplace
able and their preservation the ultimate goal in any conservation exami
nation, samples are removed only when necessary. Nondestructive
techniques ( X-ray fluorescence [XRF] , X radiography, IR and ultraviolet
[UV] photography, etc . ) should receive priority and are often used to
survey obj ects. Physical testing methods-such as measurement of color,
hardness, and porosity-may at times be in situ analyses. However, most
chemical analysis techniques require sample removal. Table 3 . 1 com
pares the capabilities of IR spectroscopy to other commonly used chemi
cal analysis techniques. Each technique has its own advantages, and
when techniques are used together, they can supply complementary
information on a sample.
The range of materials used in art obj ects is nearly universal.
Inorganic substances are found as base materials ( stone, metal, glass,
ceramic ) , as colorants ( pigments), as thickeners and fillers, as polishers
(talc, alum, carbonates), as stabilizers and neutralizers, and as unwanted
reaction products (corrosion, weathering crusts, salt deposits ). Organic
materials in objects may have either natural or synthetic sources. Both
plants and animals generate natural products (cellulose, hair, skin, resin,
gum, dye, oil, protein, wax) that are themselves complex mixtures of
Tab le 3.1
chemical compounds, even before being prepared for use as art materials.
A comparison of com monly used chemical
In contrast, synthetic organic materials ( found as fibers, colorants,
analysis tech niq ues.
binders, adhesives, plasticizers, coatings, backings, supports) are, in
Minimum
sample
size
Sample
preparation
Sensitivity
Specificity
Tech nique
Acronym
Description
Polarized light
microscopy
PLM
Ide ntification of material
based on physical properties
5 fJm
easy
n/a
none
I R spectroscopy
IR
Compositional analysis of
organic and inorganic
compounds
1 0 fJg
easy
10%
none
X- ray fl uorescence
XRF
Elemental analysis
nondestructive
1 m m spot
none
0.1 %
elements only
(heavier than
potassium)
Energy dispersive
spectroscopy
EDS
Elemental analysis (sim i lar to
XRF but attached to scan n i n g
electron microscope)
1
easy
0.1 %
elements only
(heavier than
carbon)
X- ray diffraction
XRD
Compositional analysis of
crystalline materials
1 0 fJg
easy
5%
crystalline
materials
I n d u ctively coupled
plasma
ICP
Quantitative/qualitative
analysis of elements down
to trace levels
1 mg
slow
0.01 ppm
elements only
(heavier than
nitrogen)
fJ m spot
Q uantitative/qual itative
analysis of organic components
Ch romatography
Thin- layer
liqUid
TLC
H PLC
Gas
GC
in a mixture
(TLC usually only qual itative)
High performance liqUid
chromatography
1 mg
1 pg
slow
slow
5%
1 fJg
slow
0.01 ppm
0.01 ppm
General class of
materials in
mixture must be
known before
starting analysis
Chapter
18
3
general, originally produced as well-defined, purified materials; they may
later be combined for use in commercial products. In most cases, IR
spectroscopy, since it is a nondiscriminatory technique, is one of the first
analysis methods chosen. Table 3 .2 indicates the general order in which
common analytical methods are usually applied. Information on the
microscopic characterization of particles, another common first-choice
technique, can be found in McCrone and Delly ( 1 973) and Aldrich and
Smith ( 1 99 5 ) .
I n the analysis of complex materials, such as paints, several
analytical methods are usually needed to produce a complete characteri
zation of a sample's components. Elemental analysis of the inorganic
Table 3.2
Common analytical methods and the gen
eral order i n which they are applied to var
ious organic and inorganic materials ( l R
=
infrared spectroscopy [compositional
analysis of organ ic/inorganic compounds] ;
XRF
=
X-ray fluorescence [nondestructive
elemental analysis]; EDS = energy disper
sive spectroscopy [same information as
XRF but requires sample]; PLM
==
polarized
light microscopy [size, color, shape, crys
tal l i n ity, refractive index, etc.]; XRD
X-ray diffraction [compositional analysis of
==
== ,
= =
crystalline materials]; I C P
ind uctively
coupled plasma [quantitative elemental
analysis]; UV /Vis
ultraviolet/visible spec
troscopy [precise color measurement];
fluorescence
UV-induced fluorescence
[both autofluorescent and with reactive
dyes]; color
sol ubility
visual color assessment;
Material
Fi rst-choice
analysis methods
Other useful
analysis methods
Organic
Coatings
IR
sol u bil ity, chromatography,
fluorescence
sol ubil ity, chromatography,
fluorescence
sol ubility, chromatography,
fluorescence
solubility, chromatography,
fluorescence
solubil ity, chromatography,
fluorescence
sol ubil ity, ch romatography
Adhesives
IR
Consolidants
IR
Binders
IR
Plastics
IR
Polymer additives
Sizes/fi n ishes
IR
Solvents
Air pollutants
IR
I R , chromatography
Synthetic fibers
Natural fibers
PLM, I R
PLM, I R
Dyes
Wood
I R , chromatography, U V/Vis
PLM
Organic/inorganic
Paints
IR
chem ical reactivity
tests conducted on a microscopic scale).
(with mordants, also use
XRF or E D S)
fluorescence
XRF(EDS), IR, PLM
XRD, solubil ity, chroma
tography, fluorescence
Lacquers
XRF(EDS), IR, PLM
XRD, sol ubil ity, chroma
tography, fluorescence
Residues
XRF(E DS) , I R, PLM
Patinas
XRF(E DS) , I R , PLM
Corrosion products
U n knowns
XRF(E DS) , I R , PLM, XRD
XRF(E DS) , I R , PLM
XRD, solubil ity, chroma
tography, fluorescence
XRD, solubility, chroma
tography, fluorescence
ICP
XRD, solubil ity, chroma
tography, fluorescence
solvent solubility testi ng;
m icrochemical tests
solubil ity, ch romatography,
fluorescence
ch romatography
specific compound
detectors
Inorganic
Pigme nts
Gems
Glass
Ceramics
Stones
Masonry
Mortars/plasters
Fillers (inorganic)
Salts
Metals
color, XRF(EDS), PLM, I R
color, XRF(EDS)
XRF(E DS)
XRF(E DS) , PLM
XRF(EDS) , PLM
XRF(E DS) , PLM
XRF(E DS) , PLM
XRF(EDS) , PLM, I R
XRF(E DS) , PLM, XRD
XRF(E DS) , metallography
XRD, microchemical tests
I R , XRD
ICP
IR, XRD, ICP
IR, XRD
IR, XRD
IR, XRD
PLM, XRD
IR, microchemical tests
ICP
Sample Col l ection and Preparation
19
material i n a paint sample can indicate the presence of certain com
pounds otherwise not obvious from the IR spectrum. Additionally, in an
IR spectrum of a multiple-component sample, knowledge of one material
simplifies the identification of the remainder. Thus, the complementary
use of other analysis techniques ( such as scanning electron microscopy
[SEM] , XRF, X-ray diffraction [XRD ] , optical microscopy, etc.) in con
j unction with IR is very helpful. The data resulting from each method
can be fit together as pieces in a puzzle, with the addition of each piece
bringing it closer to completion. For further information on the potential
and strategy of combining multiple analytical techniques for the charac
terization of samples from works of art, see Masschelein-Kleiner, Heylen,
and Tricot-Marckx ( 1 96 8 ), Schreiner and Grasserbauer ( 1 9 8 5 ) , Roelofs
( 1 9 8 9 ) , Karreman ( 1 9 8 9 ) , and Erhardt and coworkers ( 1 9 8 8 ) .
Sampling location
When the removal of samples is permitted, the value of the obj ect and its
state of deterioration often dictate very specific restrictions on the num
ber, size, and location of the samples removed. The obj ect's history, pre
vious analyses, treatments, revarnishing, and retouching are considered
in the sampling design. In view of the complexity and variety of possible
components in a sample from an art obj ect, the first step for its analysis
is to obtain all the background information possible. This measure can
substantially reduce the amount of time necessary for sampling and for
the later spectral interpretation, as well as minimize the chances for erro
neous conclusions.
Questions, such as the following, should be asked before the
sample is taken:
••
•
•
What is the background of the object?
What is the reason for analysis?
What information is needed ?
What is the desired format for results ?
Can a sample be removed? If so, how much? Where ?
Does the sample have a single component or is it
multicomponent?
Are all components original to the piece?
Has any previous analysis been done ?
After background information has been obtained, the obj ect
is thoroughly examined in visible and UV light to evaluate its condition
and homogeneity, as well as to inspect potential sampling sites. All infor
mation is recorded. Then, when possible, all involved personnel-conser
vator, curator, and scientist-discuss the sampling plan and make a j oint
decision as to sample numbers, locations, and amounts.
In the simplest sampling decision, an unknown contains a single
homogeneous component or matrix. Examples include a new sheet of paper,
a uniform varnish layer, an adhesive from one location, or a modern
( unaged) sculpture out of a single metal or polymeric resin. In these situa
tions, a sample can be taken from any location, and the analytical results
20
Chapter
3
will be the same. However, a homogeneous, single-matrix situation is more
often found in manufactured objects than in works of art.
For an inhomogeneous matrix or set of objects, the ideal
sampling protocol is to assign an identifier to each obj ect or sample loca
tion ( such as with a grid) and to select randomly the objects or sites for
analysis. This method will provide a statistical basis for sample selection.
If cost, time, or value of an obj ect limits the number of samples that can
be taken, then visual classification of the obj ect by color, texture, struc
ture, UV fluorescence, and so on, can be used to j ustify minimizing the
sample number and locations.
It is rare that a random and truly representative sample is
removed from a valuable obj ect. More often " convenience" samples are
selected because of their accessibility or because they can be taken from
regions of previous damage. For example, a typical sampling procedure ·
for a surface finish from a museum furniture object is to remove one or
two barely visible samples «
50 fJ..g) from arbitrarily chosen, obscure
areas near or under metal mounts, in the rear of the carcass, or on the
legs. In such circumstances, the sample may not be truly representative
of the obj ect. However, with care and knowledge of the situation, good
data can still be obtained and j ustified as valid when combined with
background information and visual examination results.
Sampling Implementation
Sampling implementation is the collection and preparation of the sample
for analysis. Once the analyst has removed or received the sample, addi
tional steps may be taken to prepare it for a specific analytical method.
As it is the sample that determines the quality and utility of the results,
care is taken in each step of its removal, storage, preparation, and analy
sis to prevent contamination or loss. Appropriate sampling tools and
containers for storage are necessary to keep the sample from changing
prior to analysis.
Tool s
Several types of sampling tools are useful for the mechanical removal of
a sample (Fig. 3 . 1 ) . Fine-point forceps are appropriate for samples that
are visible to the naked eye. Smaller particles may be manipulated with
a tungsten needle with an extremely fine ( 1 fJ..m ) point. A tungsten needle
is prepared by heating the tip of a tungsten wire (3 cm of 24 or 26 gage
wire attached to a wire holder) to red hot in a burner, then quickly draw
ing it through sodium nitrite ( McCrone and DeIly 1 9 73; Teetsov 1 977).
Another fine-point probe for manipulating small samples can be made
from a cat hair or a thick human eyelash that has been adhered to a
wooden stick ( Reid 1 972 ) . Also helpful in retrieving small particles is
a fine artists' brush (no. 2 or no. 3) or a brush modified to contain only
a few bristles. The static electricity in a small sliver of cured silicone,
freshly cut from a flexible mold, makes it extremely useful for picking up
and transferring small particles. Fine-tip paper points, available from
21
Sample Collection and Preparation
�-
Disposable scalpel blade in universal metal handle; both
pointed- and curved-end blades are useful for sample collection.
Disposable1llade prepared from a cut razor blade and a wcoden stick.
BC=======�
______________�
�
L-
Disposable eye blade in a 3 inch (7.62 cm) Beaver blade
handle; this blade is useful for removing cross sections.
________________________----
----
�L- �c=
An inexpensive artists' brush with all but a few bristles removed;
the brush fibers are useful for picking up groups of particles.
-
D
c=
A tungsten fine-point needle in a universal metal handle; a fine
point needle is used for separating and transferring single particles.
Figure 3 . 1
Several types of sam pling tools.
An eyelash brush prepared by adhering an eyelash or cat hair to a wooden
stick; this tool is useful for handling fragile particles or thin sections.
microscopy supply companies, may also be used for picking up tiny par
ticles; dampening a point with a microdrop of distilled water creates a
tool that will pick up the most obstinate particle; however, this treatment
subsequently makes it difficult to release the particle into a container.
Scalpels are used to remove barely visible particles as well as
multiple-layer cross section samples. Microsurgical scalpels have sharp,
thin blades that work well; of particular note are eye blades. Another
option is a microscalpel made by adhering 1 -2 mm broken from a razor
blade to a sharpened wooden applicator stick ( Hill 1 9 8 9 ) . With any
tool, it is important that the cutting or sampling end is immovably
secured to the handle.
Sample removal and subsequent sample preparation require
a steady hand. The probe or scalpel should be held at a low angle to the
working surface (McCrone 1 9 8 2 ) . Optimally, the working hand and arm
should be supported on a vibration-free surface. This is rarely possible
during the sample removal step, unless an exterior bridge ( boom arm,
stool, scaffolding) is available, since the obj ect itself should not be used
as a support. The sampler's other hand can be used to steady the work
ing hand, provided it is not required for holding the sample container.
Sample documentation and storage
Documentation of samples is crucial for understanding and interpreting
the analytical results and relating the sampled area to the conservation
22
Chapter
3
problem. Proper documentation starts with a picture of the object (e.g., a
photocopy or a Polaroid) on which the explicit sampling areas and dis
tinguishing features can be marked. Corresponding labels are placed on
sample containers, with the date of sampling and the initials of the sam
pler noted. All pertinent information is recorded in a sampling notebook.
This information includes a complete description of the object, the sam
pling area, and the sample, along with the reason for sampling and the
potential types of analyses.
Each sample is placed in its own well-labeled container.
Containers can introduce their own sets of problems. Plastic containers
(BEEM capsules, Ziploc bags, etc. ) often produce static electricity that
hinders the addition and removal of samples. Also, additives in and on
plastic containers ( such as slip agents added to plastic bag surfaces to
keep them from sticking together) readily contaminate samples. Samples
in solution should never be placed in plastic containers because of the
potential for leaching of plasticizers or dissolution of containers. Gelatin
capsules should also not be used for sample storage, as they may hamper
the determination of the presence of proteinaceous materials within the
sample. Organic samples are best contained in clean glass containers,
such as a depression slide sandwich ( described below) or a vial with a
Teflon-lined lid. Aluminum foil is an acceptable alternative.
A glass depression slide is ideal for small samples. A standard
microscope slide can be placed on top of the depression slide to serve as a
lid; tape hinges can be added on one side and a tape latch attached to the
other (Fig. 3 . 2 ) . The cover slide provides protection as well as a suitable
flat area for the required labeling or coding. The primary advantage of the
glass depression slide container is that samples can be examined and pho
tographed with an optical microscope multiple times without the con
tainer being opened, so that opportunities for contamination or loss are
minimized. When the cover is removed, the sample is readily accessible to
scalpels, tungsten needles, cured silicone rubber slivers, or other probes
Tape latch, with end
folded over for easy lifting
Figure 3 . 2
A sample holder made from a single
Glass cover slide
depression glass slide with a standard glass
microscope slide as a cover. Single-sided
(3 x 1 in. [7.62 x 2.54 cm])
Tape hinges
transparent adhesive tape is used to make
h i n ges and a latch . The tape latch should
be placed on the cover slide and not on
the depression slide to m i n im ize the
chance that the sample might become
attached to the adhesive.
0
Single depression slide
(3 x 1 in. [7.62 x 2.54 cm])
Sample Collection and Preparation
23
used to select and transfer a portion for analysis. The slide sandwich also
allows the samples to be carried and stored in microscope slide trays.
Avoidance of contamination
Sample purity is always a primary concern, especially in microanalysis,
where contaminants, such as dust particles, can be as large as or larger
than the sample. There are numerous means by which a sample may
become contaminated, and it is always best to analyze a sample blank as
a check. A sample blank should be exposed to all environments and come
into contact with the same materials and solvents as the sample itself.
The most common sources of contamination are unclean sam
pling tools, storage containers, and analytical support materials, such as
IR windows. Remnants from previous samples can be incorporated into a
new sample, producing a deja vu spectrum. Storage containers-such as
plastic vials, bags, and lid liners-can pollute the sample with particu
lates, plasticizers, and processing oils. Glass slides, even though marked
"precleaned," may be covered with a thin layer of formic acid, calcium
carbonate, sodium sulfate, or silicates ( Sommer and Katon 1 9 8 8 ) .
Whenever solvents are used, chromatographic o r spectroscopic grades
should be selected to minimize contamination from solvent impurities.
Residual impurities in solvents, as well as contaminants, such as sili
cones, from capillary pipette holders, are readily detected by the exami
nation of residue left after evaporation of a solvent drop on a glass slide
or IR window.
Environmental substances can taint a sample before or after
it is removed from the obj ect. Fibers (natural, synthetic, and hair) are the
most commonly recognized contaminants in nonfiber samples. Inorganic
particulates, such as quartz, clay, gypsum, and calcite, are generally soil
related; it is difficult, if not impossible, to tell whether the soil source is
current contaminant ( nonsignificant) or from the weathered crust of the
obj ect (potentially significant) . Organic materials may also be distributed
as airborne matter. Activated carbon particles may come from the air
conditioning and filtration system. Plants, insects, animals, and humans
are the sources of oils and protein bits that may produce potentially
ambiguous results in the analysis of art materials containing natural
products. Work areas and containers should be clean, and sample han
dling with bare fingers and powdered gloves (containing talc, starch, etc . )
should b e avoided. Optical surfaces should not b e sprayed with com
pressed air from canisters, as the spraying may leave a fine residue of oil
on the surfaces ( Leyshon and Roberts 1 9 8 3 ) .
Lang and coworkers have identified a number o f common
contaminants that make IR microanalysis very difficult (Lang, Katon, and
Bonanno 1 9 8 8 ) . An excellent chapter on the detection and identification
of contaminants commonly found in laboratory samples has been pub
lished by Aldrich and Smith ( 1 9 9 5 ) . Launer provides an extensive list of
spurious IR absorption bands that may be due to contaminants (Launer
1 9 6 2 ) . Of particular interest on the list are the bands that are attributed
to internal impurities in halide windows (see Table 4.2).
24
Chapter
3
Sample Collection and Preparation Procedures
Many, if not most, samples will be analyzed by more than one method.
Thus, unless additional samples can be obtained easily, the entire sample
must never be used during any single sample preparation step. If a small,
irreplaceable sample must be used in totality, it should first be analyzed
by a noncontaminating, nondestructive method, such as optical micros
copy or IR micro spectroscopic analysis-after which it can be retrieved
and stored for further testing.
Good laboratory practices are important. Sample documen
tation, which began during the collection phase, is continued, with all
preparation steps recorded in a lab notebook. Photomicrographs are
obtained on the sample whenever possible. If not, drawings and visual
observations are recorded. This procedure helps to distinguish the physi
cal characteristics of the sample. Subsamples, such as solubility fractions
or isolated inhomogeneous particles, are always labeled accordingly,
along with identification of the parent sample.
The following describes a possible sample preparation proce
dure for a multilayer paint sample after its arrival in the lab. The sample
is examined under a stereomicroscope, and a drawing or photograph
with colors and relative sizes noted-is made of the visually discernible
layers. Particles are removed for further characterization and identifi
cation by polarized light microscopy, if this has not already been done.
Then a small portion of the sample (no more than half) is embedded.
After polymerization of the mounting medium, the embedded sample is
microtomed. This method achieves two goals: First, thin sections are pro
duced for analysis by IR transmitted light. Second, a flat, even surface
is obtained on the remainder of the embedded cross section, so that the
effort required for polishing the surface is minimized. At this point,
photomicrographs, in visible and UV light, are taken of the cut surface,
preferably adj acent to the thin section layer removed for IR analysis.
Later, if desired, the embedded residual sample can be used for IR
reflectance mapping studies, SEM, and fluorescent staining. The compiled
data set from these analyses should give a clear image of the structural
composition of the paint sample . The unembedded portion of the sample
is retained for later chromatographic studies or for additional embed
ments, if problems arise from the first sample.
In the interrelated sampling scheme, the steps required for
sample collection and preparation depend not only on the analysis meth
ods but also on the type of sample (Table 3 . 3 ) . The following sections
discuss a variety of sample collection and preparation procedures that
apply to IR analysis, as well as to other analytical methods. The IR
specific techniques mentioned in this section are described in chapter 4 .
Gases
IR analysis is rarely used to monitor pollutant levels within museums and
display cases because these are relatively clean environments, with low
level contaminants that are better measured by quantitative techniques
such as chromatography. IR analysis can, however, be used to perform
25
Sample Collection and Preparation
Sample type
Examples
Potential collection
methods
Potential preparation
methods
Potential analysis
methods
I n situ nondestructive
analysis
surface studies
none
none (possible
precleaning)
Photography ( I R , UV,
etc . ) ; XRF
Gas
pollution measurements;
h u m idity studies
none; syringe; flow
through cells; pump;
sorbent tube
none; desorption;
derivitization;
preconcentration
IR; G C ; H PLC; colorime
try; visual indicator
Liquid
residue; exudates; pre
polymer components
syringe; capillary tubes;
swab; sorbent
none; solvent evapora
tion ; derivitization
I R ; GC; H PLC; TLC
Solid
Solvent-soluble
coati ng; adhesive
solvent-soaked swab
extraction; solvent
evaporation;
derivitization
I R ; GC; H PLC; TLC
Solid
Particles
corrosion layer; stone;
pigment; coating; alloy;
adhesive
scraping; scalpel; for
ceps; probe; silicone
sliver
mounting; physical sep
aration; grinding;
flattening; dissolution;
derivitization
I R; G C ; H P LC; TLC;
SEM/EDS; PLM; fluores
cent microscopy; chemi
cal microscopy; XRD
Solid
Cross section
painting; alloy; weath
ered crust
scalpel; needle; drill
mounting; physical sep
aratio n ; grinding;
embedding; microtom
ing; derivitization
I R ; GC; H PLC; TLC;
SEM/EDS; PLM; fluores
cent microscopy; chemi
cal m icroscopy; XRD
Solid
Fibrous
textile; contaminant;
basket
forceps; probe
none; mounting;
embedding; flattening;
cutting; extract dye
IR; PLM; S EM/EDS;
UV!Vis
Table 3.3
Sample types and related sample collec
= gas chromatography; H PLC = high
tion, preparation , and analysis methods
(GC
= polarized light microscopy; SEMI
= scan n i n g electron microscopy with
energy d ispersive spectroscopy; TLC =
thin -layer chromatography; UV!Vis =
u ltraviolet/visible spectroscopy; XRD =
X-ray diffraction; XRF = X-ray fluorescence).
comparative studies of environments, evaluate changes in atmospheres,
and identify some offgassing materials. Koestler demonstrated that IR
spectroscopy could be used to detect the by-products of insect activity in
an inert atmosphere (Koestler 1 99 3 ) . A later example in this book shows
performance liquid chromatography;
the effectiveness of gas-phase IR measurements in the evaluation of the
PLM
interaction of a reactive gas ( Vikane) with different types of materials
EDS
( chap. 6, case study 7).
When a gaseous environment is to be analyzed, a sample
may be collected by ( 1 ) opening an evacuated gas container in the area of
interest, (2) pulling an air sample into a gas syringe, or ( 3 ) using a pump
to make the air flow over a sorbent that will specifically trap the compo
nents to be analyzed. Due to its volatility, a collected gas sample should
be stored at cool temperatures and analyzed as soon as possible.
Alternatively, the IR gas cell may be used as a collection
device for an in situ experiment, where the analyte gas is produced from
a sample within the gas cell via some process, such as a chemical reaction
or heat. In this case, the sample is kept out of the beam path, so that
only the atmosphere in the cell is measured. Outside the laboratory,
portable long-path length IR monitors are available for the measurement
of gaseous environments ( see Suppliers, Midac Corp . ) .
Liquids
Liquid samples encbuntered in the analyses of art materials are usually
in the form of solvents, uncured materials ( coatings, adhesives, etc . ) , or
exudates on the surface of obj ects. In any case, a liquid sample should
be collected and stored in a well-sealed glass vial with a Teflon-lined lid.
26
Chapter
3
Small droplets of a liquid can be collected with a capillary tube that is
used to draw up the liquid. The capillary can be placed in a glass vial
for labeling. A scalpel may occasionally be used to collect a small vis
cous drop and to place it in a glass depression slide. Teetsov describes
the use of a small, 0.2-0.4 mm polyester filter square to collect a very
small volume of nonvolatile liquid from the surface of an obj ect (Teetsov
1 99 5 ) . Alternatively, a swab may be used to collect the liquid sample
( see below for cautions regarding the use of swabs ) . However, with
either of the last two procedures, it may be difficult to extract the liquid
from the swab or filter later, if the liquid (or a portion of it) is insoluble
in common solvents.
Liquids generally require very little sample preparation. For
IR analysis, volatile liquids can be analyzed directly by use of a commer
cial liquid cell or simply by sandwiching a drop between two salt plates.
A liquid sample that is nonvolatile or of low volatility can be analyzed
by a procedure of spreading one drop on a single salt plate or other
transparent surface, such as a single surface of a diamond cell (two
diamonds should not be put together, or the liquid will be displaced ) .
Alternatively, a few drops o f the liquid may b e dripped onto a bed o f
powdered potassium bromide (KBr) for analysis b y diffuse reflection.
Liquids may also be analyzed with an internal reflection cell. This tech
nique works particularly well with liquids that contain water.
Sampling with swabs
Solvent-dipped swabs are used to conduct solubility studies and to collect
samples when the analysis pertains to a solvent-soluble surface of an
object, such as a patina or coating on a bronze sculpture. The sampling
area can range from a few millimeters to a centimeter in diameter, depend
ing on the size of the swab and the prominence of the area in question.
Commercially purchased cotton swabs or applicators should
not be used for this type of sampling because the cotton is typically
adhered to the stick by an adhesive, such as poly(vinyl acetate } . Instead,
swabs for analysis should be prepared by winding a small piece of cotton
fiber, gauze, nylon, polyester, or additive-free clean-room wipe onto the
end of a wooden stick ( Fig. 3 . 3 ) . The smaller the point of the wooden
stick, the smaller the swab. Selected fibers, wipes, and sticks should be
tested before sampling to ensure that they will not be a source of conta
mination. A sharp, pointed stick, such as an uncoated toothpick, is
needed to prepare a tiny swab. The sampling end of the stick and the
swab should be handled only with tweezers to prevent contamination
from skin cells and oils. After preparation, the swabs may be wrapped
in coating-free aluminum foil for storage.
When sampling preparations are complete, the selected area
on the obj ect is lightly swept with a sable artists' brush to remove any
loose particles or dust. A drop of an appropriate solvent (water, ethanol,
acetone, chloroform, hexane, etc.) is put on the swab, which is then
rubbed over the small area on the object. Multiple samples taken with
swabs treated with different solvents may be collected from the same
sampling area. After collection, each sampling swab is placed in a clean
27
Sample Collection and Preparation
�
Forceps
Wood," ""k
Rotate clockWise
Cotton fibers
Swab
��
Aluminum foil
��========== ==== ::== :::J
Wrapped swab (may be stored until use)
Rotate clockwise
Place solvent drop on swab, then place swab on object,
hold at a low angle, and rotate swab to collect sample.
Figure 3 .3
I n - house fabrication of a cotton swab and
collection of a solve nt-soluble sample from
After sample collection,
place swab in clean vial,
break end of stick,
seal vial, and label.
the surface of an object. An alternative
proced u re is to use small squares of clean
room wipes for swabbing; they should be
held with forceps for sample collection,
then placed in a vial for storage.
glass vial; either the stick is removed or its end is broken off; and the vial
is sealed and labeled.
Samples obtained by solvent-dipped swabs or filter squares
contain the evaporation residue of the solvent-soluble portion removed
from the sampled area on the object. For analysis, the residue is extracted
from the swab with the same solvent that was originally used to acquire
the sample. A corresponding blank should be prepared to check for conta
mination from solvents, capillaries, or other contact sources.
Swab sampling is not recommended when any other choice is
available. While the solvent swab removes the soluble portion of a sam
pled area, it may be difficult to determine whether the swab sample con
tains only the surface coating or whether it also contains some leachate
from lower layers. Additionally, particles may be removed by abrasion.
Thus, this selective but nonspecific removal can create confusion in the
analysis scheme. When possible, it is better to remove a scraping and
perform solvent solubility tests under the microscope.
28
Chapter
3
Solids, powders, and particles
Samples consisting of fine powders or crystalline particles are often
collected when the analysis question pertains to pigments, stone sur
faces, corrosion products, adhesives, or coatings. Loose samples can be
acquired with a fine-tip brush. Single particles can be picked up with a
tungsten needle or a cat-hair probe. In cases in which particles must be
scraped from a surface, a scalpel is used. The scalpel blade is held at a
low angle, and the blade is pulled backward or away from the cutting
edge ( Fig. 3 . 4 ) . This technique a brades only the very top surface and
minimizes the chance of accidental damage ( from slicing or gouging) to
the obj ect. The particles will often cling to the scalpel; this tendency
aids in the transfer of particles from the object's surface to a glass slide.
When the sample surface is not horizontal, it is best to hold (or have
someone else hold) the slide directly below the sample area to prevent
possible loss of valuable particles that fall as they are loosened. It is
advisable to wear gloves ( cotton, latex, or other gloves appropriate to
the object) to protect the obj ect, sample, and future samples from
contamination.
The preparation procedure selected for solid materials
depends on the form and homogeneity of the sample. For IR analysis, a
homogeneous sample can be ground or filed to form fine particles, then
analyzed by either KBr pellet, KBr micropellet, diffuse reflection, internal
reflection, diamond cell, or microscope. Although inhomogeneous
samples, such as mixtures and multilayered paints, can be analyzed
directly, the characterization of each component is simplified by the use
of a physical or chemical preseparation step prior to analysis .
Drag scalpel away from
the cutting edge to lightly
abrade the surface.
of movement
Figure 3 . 4
The proper u s e o f a scalpel t o remove
particles from the surface of an object
for analysis. Alternative procedu res involve
a fine brush for gathering loose particles
or a tungsten needle for removing a
single particle.
to the surface of the object.
Static from the abrasion
usually causes the particles
to cling to the scalpel.
29
Sample Collection and Preparation
Mixture separation by solvent extractions
Similar to separation experiments described by Gettens, solvent extrac
tions can be performed on multiple-component particles to identify indi
vidual components ( Gettens 1 95 9 ) . For this procedure, a sequence of
solvents is used to selectively remove one or more components in a mix
ture; after each extraction step, IR spectra are collected from the soluble
and insoluble portions of the analyte. A secondary benefit is that the sol
ubility information from the extraction can also aid in the identification
of components. This method is especially useful when the IR spectrum of
a bulk sample of a coating or consolidant is difficult to identify because
of the presence of other components, particularly inorganic fillers or pig
ments. Figure 3 . 5 is a solubility schematic for many natural and syn
thetic materials.
For solute extraction of macrosamples (e.g., a swab sample
xf.11).
or a particle large enough to be seen with the naked eye), the sample is
placed in a micro test tube (5
of solvent (about 1 0- 1 00
35 mm), then covered with a few drops
The test tube can sit for about an hour or
can be briefly agitated in an ultrasonic bath. A micro drop ( 1-5 f.1l) of the
extract is removed with a capillary tube or micropipette; the microdrop
is then placed on an inert IR window ( such as barium fluoride, BaF2 ) for
IR microspectroscopy analysis, or it is dripped onto KBr powder for
pressing a salt pellet or for diffuse reflection analysis. The solvent is then
Figure 3 . 5
A so lubility schematic for many natural
allowed to evaporate. The drop procedure may be repeated to concen
and synthetic materials.
trate the amount of sample for analysis .
Sample
+
Soluble in hexane?
(organic solvent-low polarity)
yes
!
Polyethylene (partial)
Hydrocarbon waxes and oils
Paraffin
Mineral oil
Ceresine wax
Carnauba wax
Beeswax (usually)
Some plasticizers and
slip agents
�I
Soluble in ethyl acetate?
(organic solvenl-high polarity)
yes
!
Insoluble in chloroform
Cellulose acetate
Cellulose nitrate
Methyl cellulose
Ethyl cellulose
Polyvinyl chloride
Epoxy (uncured)
Urethanes (some)
Soluble in chloroform
The following solvents may
be substituted:
Acetone for ethyl acetate
Methylene chloride for chloroform
Toluene for benzene
Formic acid for cresylic acid
Polystyrene
Polyvinyl butyral
Poly(vinyl acetate)
Acrylics
Cellulose acetate butyrate
Silicones
Natural resins
ABS rubbers
Alkyds
Plasticizers
Beeswax
Soluble in chloroform but
insoluble in ethyl acetate
Polyesters
Cellulose triacetate
no
Soluble in benzene?
no
�
Soluble in water?
(organic solvent-aromatic)
yes
!
yes
!
Crystalline residue
Polyvinyl chloride
Natural resins
Elastomers
Polystyrene
Polyethylene (hOI)
Polypropylene (hot)
Indene resins
Rubber (natural)
Polybutadiene
Polyisoprene
Cellulose esters
Polyesters (some)
Salts
Amorphous residue
Proteins (hot)
Sugar, pectin, gums
Starch, dextrin (hot)
Polyvinyl alcohol
Methyl cellulose
Acid-sensitive minerals
Nylon
Drying oils
Formvar (baked)
Alkyds (baked)
Polyester (baked)
Insoluble
Minerals, pigments
Proteins (egg)
Urethanes
Teflon
Epoxy (cured)
T
no
yes
Soluble in cresylic acid?
(organic solvent-acid)
�
30
Chapter
3
For smaller samples, a micro drop ( 1-5 fLl) of solvent is
placed directly on a sample that is on an inert window or glass micro
scope slide ( care must be taken that the drop cover only the sample of
interest and does not spread over other samples, and that the solvent
chosen does not react with the substrate ) . Any soluble portion of the
sample will dissolve and be deposited away from the insoluble material
as the solvent evaporates. Depending on the solvent and the solute, the
deposition may appear as a solid film, as droplets in a ring at the former
Uniform film layer.
sometimes thicker at the edges
edge of the solvent, or as a dried puddle ( Fig. 3 . 6 ) . The most highly
soluble materials-such as waxes, synthetic resins, gums, and inorganic
nitrates-will form a solid film that often has a more concentrated region
at the exterior rim. Such analytes as nondrying oils, waxes, and natural
resins tend to form a ring of droplets. " Before" and " after" photos for a
mixture of natural resins extracted with chloroform are shown in Figure
3 . 7 . In the analysis of many art materials, water-soluble proteins have
been found to occur most often as dried, wrinkled puddles near or under
the original sample. To identify these new puddles, it is desirable to have
a good visual memory or a photograph of the sample prior to the solvent
Ring of droplets at the former
edge of the solvent drop
drop . Because multiple components might have been extracted and
deposited in different areas, it is also important to collect IR spectra
from all visually different areas after each extraction.
Multiple extractions and analyses can be done sequentially
on the same sample. The selection of solvents for a series of microextrac
tions depends on the components expected to be in the sample . For a
sample thought to be composed of natural products, a typical solvent
series would start with a drop of hexane to extract nonpolar components
such as mineral waxes. After the drop has evaporated and the spectrum
collected, a second solvent is selected-typically either ethyl acetate or
chloroform-to check for the presence of other waxes, natural resins,
Dried puddles of solute that
may appear shriveled and may
exist in addition to a ring
Figure 3.6
Possible deposition patterns for sol u ble
components extracted from a sample with
a d rop of solvent. With IR m icrospec
troscopy. a spectrum can be collected of
the solvent-so l u ble and solvent- i nsol u ble
fractions.
nondrying oils, and many synthetic resins. If multiple components are
extracted at this point, then ethanol or acetone is used for further sepa
ration. The final solvent is usually a drop of water to check for the pres
ence of carbohydrates or soluble proteins. After the drop of water is
placed on the sample, the pellet is positioned under a warm light to heat
the water; this procedure increases the solubility of many proteins while
also hastening the evaporation of the droplet. After each drop dries,
spectra are collected at several positions around the deposition ring.
Once the solvent series is completed, the insoluble residue of the sample
is analyzed. It is also important to analyze a blank for each solvent.
The same extraction procedures can also be done on a gold
mirrored surface; the IR spectra are then collected by reflection measure
ments. Because of the nonreactive surface of gold, acids and bases may
be used to further characterize the sample components. A sample with a
high content of drying oil can be treated with a 5 % solution of sodium
hydroxide to saponify the oil and separate it from the pigment particles
( Gettens 1 95 9 ) . Alternatively, a drop of concentrated nitric acid placed
on the sample and warmed to dryness will solubilize most oil and resin
media. A drop of concentrated sulfuric acid will extract many colorants
from dyed fibers (Saltzman and Keay 1 9 72 ) . The acids and bases will
Sample Col l ection and Preparation
31
Figure 3 . 7
The separation of components of a carved
resin sculpture by solvent extraction. The
top photograph shows a sample placed on
a BaF2 window for I R microanalysis. The
lower photograph shows the same sample
after a microdrop of chloroform was
placed on the sample, then allowed to
evaporate. Two d istinct components were
separated. The chloroform -soluble compo
nent, later characterized as a pine res i n ,
primarily collected i n a r i n g a t t h e former
edge of the droplet. A chloroform
insoluble portion , later characterized as
copal, was concentrated as a residue i n
t h e center. I R spectra were collected o n
t h e b u l k sample, a s well a s from several
regions of the extract and residue.
also react with some pigments and thereby provide additional informa
tion on the sample ( Gettens 1 95 9 ) .
Disposable glass capillaries used for thin-layer chromatogra
phy can be employed to dispense the microdrops of solvent required for
this procedure. However, because some capillaries have been found to be
a source of contamination, it is recommended that each capillary be
rinsed inside and out with a drop of solvent prior to use. An alternative
to glass capillaries are the polypropylene tips for the Eppendorf GELoader
(available from any scientific supply company) , as recommended by
Teetsov ( 1 99 5 ) . While they must also be rinsed, the tips can be bent with
heat to provide an improved pipette for easier control of the drops.
Mixture separation by pyrolysis
Pyrolysis is useful for the separation of small amounts of insoluble
organic materials from an inorganic matrix, such as a glass-filled epoxy
resin, a low-binder oil paint, or a polyurethane-consolidated stone. For
manual pyrolysis, it is best to have at least 1 mg of sample, as the proce
dure becomes easier as the sample size increases. Smaller samples can be
analyzed manually with careful manipulation ( Humecki 1 9 95a) or with
temperature-controlled, commercially available pyrolysis equipment.
To pyrolyze a sample manually, it is placed as pulverized
chunks or as a pile of powder inside a glass capillary tube or disposable
glass pipette with an inner diameter of approximately 1-8 mm. The
sample should be at least 1 inch (2.54 cm) from the end of the tube.
With the tube held horizontally with forceps or pliers, the sample area
only is placed in the hot spot of a flame from a Bunsen burner or a
butane lighter ( Fig. 3 . 8 ) . After the sample produces smoke, the tube is
32
Chapter
3
Pyrolysate droplets
/�
Sample
Figure 3 . 8
The manual pyrolysis technique useful for
the separation of nonsoluble organic com
pounds from an inorganic matrix. A por
tion of the sample is compactly placed
inside a glass pi pette, then heated. After
the sample smokes, the tube is cooled,
and the pyrolysate that collects as droplets
in the cooler regions of the tube is col
lected and analyzed.
removed from the flame and cooled. The volatiles in the smoke will pri
marily condense and collect as droplets in the regions of the tube not
heated by the flame. These droplets can be sampled with a metal probe
and placed on an IR transparent pellet for analysis. While in most cases,
the spectra of pyrolysates will correspond to the parent compounds, it is
best to prepare pyrolysate references for comparison.
Fibers
For micro spectroscopic analysis, fiber samples may be collected from
paper, textiles, and ethnographic obj ects with fine-tip forceps. A single
fiber can be grasped and pulled loose from its thread or mat. Some small
bristles or lint particles embedded in or attached to painted or coated
surfaces may require a scalpel for removal. When a larger fiber sample
is needed for macro IR analysis, a sharp scalpel can be used to cut the
thread while it is held in position with forceps. Since this maneuver often
requires three hands, this job is best performed by two people. Some
forensic examiners have used adhesive tape to collect loose fibers and
particles from a surface ( Ryland 1 99 5 ) . The adhesive from the tape can,
however, contaminate the surface of the sample .
Fiber, hair, and brush samples require little sample prepara
tion. They may sometimes even be analyzed "as is" by taping the ends of
a single fiber to hold it across a hole in a metal disk, or by simply laying
it on an IR window (Tungol, Bartick, and Montaser 1 99 5 ) . However, the
fiber is often too thick and absorbs too strongly for direct transmission.
In such a case, one alternative is to use a reflection method, such as dif
fuse reflection or internal reflection. When a large sample, such as a
length of yarn or a piece of textile, is available, internal reflection is a
very good nondestructive method.
A second alternative is to make the fiber thinner. The advan
tages to flattening a fiber are twofold. First, the horizontal area of the
fiber is increased. Second, the surface is now planar. The use of the
Sample Col l ection and Preparation
33
diamond cell is a quick and easy method for flattening fibers. Another
method is to press the sample between two IR transparent windows in a
compression cell. A final option is to use a scalpel to slice a thin section
from the end or side of the fiber. This method is sometimes preferred for
the examination of the fiber structure, since flattening destroys its physi
cal shape and may change its crystalline orientation.
Cross sections
When the surface of an object, such as a painting or a folk art carving, has
a complex structure with multiple layers, a cross section sample is taken
that incorporates this stratigraphy to facilitate the study of the sample.
Paint cross sections have been used for the examination of paintings for
over eighty years ( Laurie 1 9 14; Gettens 1 932). The technique of embed
ding paint cross sections was revived in the 1 950s; it quickly became a
standard method for the study of painting techniques (Plesters 1 95 6 ) .
With the use of a stereomicroscope, a cross section sample i s
removed b y cutting with a scalpel from the top down t o the bottom sub
strate. When possible, a sample is taken from the edge of the painting or
near a preexisting crack, provided that the sampling area has not under
gone previous restoration ( Plesters 1 95 4 ) . Alternate methods for cross
section removal have been tried but have not proved to be as successful
as skillful extraction with a scalpel. Laurie used a hypodermic needle,
and Gettens constructed a workable, although complex, apparatus
(Laurie 1 9 1 4; Gettens 1 93 6 ) . While these tools are useful with some
paintings, crumbling can occur with brittle paints .
Once removed, the resultant cross section sample is often too
small to be picked up with forceps and may not have enough static charge
to cling to the scalpel. In these cases, an artists' brush modified to contain
only a few bristles is used to pick up the particle and transfer it to a glass
depression slide. Occasionally, for a few obstinate samples, a short breath
of air on the brush ( directed away from the sample) will supply enough
moisture to the bristles to adhere the particle temporarily for transfer.
However, when a very sensitive analytical technique, such as gas or liquid
chromatography, is used, it is important to minimize the potential for pro
tein contamination. In these cases, the brush may instead be moistened
with a mist of distilled water (Johnson and Packard 1 97 1 ) .
Before I R micro spectroscopy was commonly used a s a n ana
lytical technique in conservation, the two usual IR sampling techniques
for the analysis of paint cross sections consisted either of examining the
entire chip or of selectively removing visually different sections for analy
sis. Both methods can misrepresent the composition of the paint. In the
first method, when an entire multilayer chip is ground into a homoge
neous mixture, usually with KBr salt to make a pellet, any stratigraphic
or layering information about the sample is lost. In the second method,
physical separation of layers is time-consuming and difficult unless the
layer is large. Small layers may be missed altogether.
To obtain meaningful analyses of multilayer media, it is
important to work with a high-quality cross section of the sample. IR
micro spectroscopic analysis can be done on cross sections with reflected
Chapter
34
3
or transmitted light. Cross section samples from paintings contain many
materials, such as binders and pigments, with various particle sizes.
These variations can produce a reflectance spectrum that, even after
mathematical corrections, looks different from the spectra collected
by transmission from the same components because of the dissimilar
reflection and absorption characteristics of each material. For the analy
sis of binders, which generally absorb IR radiation better than they
reflect it, transmission FT-IR is usually more successful. To produce
good-quality IR transmission spectra, most paint samples need to be
1 - 1 0 !Lm thick. Microtoming is normally used to prepare a thin section
of a multiple-layer sample, and an embedding medium is needed for the
support of small and fragile paint samples during microtoming. Audrey
Glauert provides an excellent reference on embedding and microtoming
procedures ( Glauert 1 9 72 ) .
Embedding media and procedures
Polyester resins have been commonly used in art conservation since the
1 950s for embedding paint cross sections prior to microscopic and analyt
ical studies ( Plesters 1 954 ) . Indeed, polyester resins have many desirable
properties for embedding resins, and they are nearly ideal embedding
media for most samples found in fine-art paintings (Table 3 . 4 ) . Polyester
resins are clear and colorless and easy to section; they cure at room tem
perature and do not react with most samples. A polyester resin may, how
ever, dissolve some compounds, such as some waxes on furniture-finish
cross sections ( Godla 1 990), organic dyes on inorganic carriers in modern
(post- 1 8 50) pigments ( Stodulski 1 994), and fresh natural-resin layers
( Derrick et al. 1 9 9 2 ) . Additionally, Derrick found that polyester resins
infiltrate porous samples ( Derrick, Souza et al. 1 994 ) .
Embedding with Polyester Resin. To embed a typical paint
sample in polyester media ( brand names are noted in Table 3 .4; see also
Table 3.4
Suppliers ) , six drops of catalyst ( methyl ethyl ketone ether) are mixed
Types and brand names of selected media
thoroughly with 10 ml of liquid polyester resin in styrene solvent. The
tested for embedding and m icrotoming of
transparent resin is initially light blue; it turns yellow when the catalyst
paint cross sections.
is well mixed, and then it quickly becomes colorless as the reaction pro-
Type
Brands
Source
Comments
Paraffin
Paraplast
Ladd Research I nd ustries
Opaque; m i n imal shrinkage; soft; cuts well; elevated
temperatures req uired for preparati o n .
Epoxy
Epon 8 1 2
LX- 1 1 2
Maraglas 655
SPURR
Ted Pella, I nc.
Ladd Research I ndustries
Ladd Research I ndustries
Ted Pella, I n c .
Generally needs elevated temperatures to cure; transparent
though sometimes yellow; forms very hard block that is
difficult to slice at
1 fJm thicknesses.
Quetol 523M
L R White
Butylmethyl-methacrylate
Exothermic cure reactions; transparent; shrinks more than
polyesters; cuts well; may infiltrate some samples; dissolves
lipids; toxic.
Krazy Glue (cyanoacrylate)
Ted Pella, I n c .
Ladd Research I nd ustries
Ladd Research I nd ustries
Borden, Inc.
Caroplastic
Bio-Plastic
Castolite
Carolina Biological Supply
Ward 's Natural Science
Casto lite Co.
Cures at room temperature; transparent; cuts well; minimal
shrinkage; may infiltrate some samples.
Acrylic
Polyester
>
Sample Col l ection and Preparation
35
ceeds (Ward's Natural Science 1 99 0 ) . Excess catalyst, while it will speed
up the curing process, will also make the final mount more brittle and
difficult to microtome. A mold is initially half filled with the well-mixed
embedding medium and cured at room temperature for 3-6 hours. A rep
resentative portion of the sample containing all the layers is transferred
to the hardened base layer in the mold with forceps or a probe and posi
tioned in the desired orientation. A label is placed on the opposite end
of the mold, then both the label and the sample are covered slowly with
freshly prepared polyester embedding medium. The embedment is cured
and nontacky within 24 hours. For microtoming of the sample for IR
microanalysis, the best results are obtained by allowing the embedment
to set 3 6-4 8 hours before slicing. The medium continues to cure slowly
over time ( Demmler 1 9 8 0 ) . After one month, the microtoming becomes
noticeably more difficult, and the samples tend to crumble . The bottom
and top halves of the block should be prepared within a few days of each
other to prevent a hardness differential between halves that interferes
with microtoming. Silicone molds, ice cube trays, and peel-away molds
are all useful for preparing embedments; some examples are shown in
Figure 3 . 9 . Because the presence of excess medium around the sample
produces stress during microtoming, most of the plastic around the
sample has to be trimmed away to reduce the area of contact with the
microtome blade. Trimming time can be minimized by the use of small
Pelco silicone rubber molds for embedding ( see Suppliers, Ted Pella,
Inc . ) . These molds produce embedments with trapezoidal tips that only
require minimal trimming prior to slicing. While small embedments are
good for microtoming, they are difficult to hold in a level position for
the polishing of samples.
Infiltration. Paints are porous when the amount of binder is
low enough that it does not fill the void spaces around the pigment
particles ( Hansen, Lowinger, and Sadoff 1 994 ) . The embedding resin can
then seep into the sample, fill these spaces, and, by doing so, coat the
particles. This is termed infiltration. Infiltration can occur with matte or
porous paints and glue gessoes . If analysis of the binder or organic com
ponents in the sample is needed, infiltration may be undesirable, and in
Figure 3.9
Molds and embedding media blocks used
for the preparatio n of embedded cross
sections.
36
Chapter
3
some cases, steps should be taken to prevent infiltration from occurring
( Derrick, Souza et al. 1 9 94). In other cases, sample infiltration is benefi
cial. It consolidates the sample to produce a smooth block that is readily
polished or sliced in preparation for analysis.
If several samples of a porous material are to be embedded for
analytical studies of the media, it is prudent to embed only one sample
initially to see if infiltration occurs and, more important, whether it inter
feres with analysis. Depending on the type of analysis, it is possible that
infiltration will not cause a problem, but it is important that the analyst
recognize that resin may be in the sample, taking that into account in any
spectral interpretation. IR spectroscopy is more sensitive to the presence
of the infiltrated resin than is visual or microscopic examination; thus,
when IR is used, it may be important to prevent infiltration.
Visual examination of a paint cross section can often detect
infiltration of the embedding resin from the discoloration or darkening of
the sample. This is particularly noticeable for white paints and grounds.
Samples that visually appear very white and opaque before embedding
can take on a darker, transparent appearance after resin penetration.
Because of the presence of embedding resin inside and outside of the
sample, there is less contrast at the sample edges, and the edges may
seem poorly defined. For example, two small portions of a sample from
a polychrome sculpture were embedded separately-one in an acrylic
medium and one in polyester ( Figs. 3 . 1 0, 3 . 1 1 ) . The sample in the poly
ester medium ( Fig. 3 . 1 1 ) shows infiltration of the resin, while the sample
embedded in the acrylic ( Fig. 3 . 1 0 ) does not. The acrylic-embedded
sample has very well defined edges, and the opaque white ground
remains white after embedding. The polyester-embedded sample visually
appears to have a more transparent, darker ground layer.
The IR spectrum of an infiltrated sample will contain absorp
tion bands for the sample components, as well as for the polyester resin .
•
Figure 3 . 1 0
A paint cross section from a painted sculp
ture i n a church i n Minas Gerais, Brazil,
embedded i n acrylic med i u m .
Sample Collection a n d Preparation
37
Figure 3 . 1 1
A cross section from the same paint chip
as shown in Figure 3 . 1 0, embedded in
polyester med i u m .
The polyester resin produces numerous strong absorption bands.
Theoretically, the absorption bands for the polyester could be subtracted,
but the subtraction process can distort the remaining bands in the spec
trum, thus limiting the detection of other components. Many binding
media are present in low concentrations and have absorption bands at
wavenumbers similar to those of polyester, making the binder especially
difficult to detect. Since infiltration of polymer severely inhibits the IR
analysis of the sample, several methods for preventing this occurrence
were examined ( Derrick, Souza et al. 1 9 94). The most successful method
discovered for inhibiting the infiltration is to precoat the sample with
a thin layer of acrylic emulsion ( Rhoplex AC-3 3 ; see Suppliers, Conser
vation Materials) thickened with fumed silica to form a gel. A thin layer
of this gel dries quickly to encapsulate very porous samples, even plaster,
thereby preventing polyester infiltration without inhibiting the optimal
slicing properties of the polyester.
Microtoming procedures
Rotary microtomes were first developed in the 1 950s. They are available
with manual and motorized cutting arms. The cutting arm moves the
clamped sample past a sharpened knife or blade to produce a thin section
of the sample. Detailed information on micro tomes and microtoming
techniques is available in Reid ( 1 972 ) .
Four types o f knives ( steel, tungsten carbide, glass, and dia
mond) are readily available for use with any type of rotary microtome
( Figs. 3 . 1 2, 3 . 1 3 ) . The steel blade is an all-purpose, inexpensive micro
tome blade that can routinely provide slices 1 5-30 J.lm thick. However,
depending on the absorption of the sample, this may be too thick for IR
analysis. Both the tungsten and the glass knives routinely produce good,
clean slices 1 - 1 0 f.Lm thick. The diamond knife is typically used for
ultramicrotomy of sections, since it should only be used to cut sections
3
38
Chapter
Figure 3 .1 2
thinner than 1 /-Lm. A general dictum is that harder samples require
A motorized rotary microtome with a
harder knives.
Of the four blades, glass knives are the easiest to use. Glass
stereobinocular m icroscope for viewing
and positioning the sample.
knives are made by scoring and breaking a 2.54 em ( 1 inch) square of
Figure 3 . 1 3
glass to create two triangular pieces, each with a very sharp edge ( Figs.
A selection o f m icrotoming blades: dia
3 . 1 4 , 3 . 1 5 ) . This procedure produces a 45° angle on the blade. The angle
mond (in the box at the upper left) , glass
may be increased for cutting harder materials and decreased for cutting
(lower left) , tungsten (lower right), and
softer materials ( Malis and Steele 1 99 0 ) . The glass knives section best on
stainless steel (in the blade holder at the
polyester-embedded paint samples containing finely ground pigments; in
upper right) .
such instances they produce transparent, cellophane-like thin sections.
Small samples are easier to microtome because smaller cutting
surface areas require less force. Cutting-surface areas that are too large
may produce sections that curl or cause layers to debond. Thus, to
reduce the size of the cutting surface, self-supporting, strong, hard sam
ples-such as polymers, laminates, and metals-should be trimmed to a
sharp point. Harder samples require finer points . The facet point for a
self-supporting polymer should be less than 0 . 5 mm; for aluminum it
•
Figure 3 . 1 4
A glass k n ife maker for t h e accu rate scor
ing and breaking of microtome blades.
Sample Collection and Preparation
39
Figure 3 . 1 5
A glass knife positioned i n the rotary
microtome. The sample is held in the
chuck and slowly moved past the station
ary knife.
should be less than 0 . 1 mm; and for ceramics, the facet should be only a
few microns (Malis and Steele 1 99 0 ) . Delicate, small, or soft samples,
such as paints, waxes, papers, or textiles, should be cut into a pie shape
and positioned in a mold for embedding, such that the point is cut first
( Fig. 3 . 1 6 ) . An embedded sample should have all excess medium trimmed
from the embedment so that only a trapezoidal facet with 1 -2 mm of
medium outside the sample at the cutting surface is left ( Fig. 3 . 1 7 ) . A
trapezoidal shape of plastic around the sample helps in later microtoming
by providing a pointed region to initiate and end the cutting stroke.
Unexpected thickness variations and j agged cutting surfaces
are often due to vibrations or movement of the sample block during
microtoming. Thus, the embedment or sample block should be fastened
tightly in the microtome chuck, and the fastening should be checked reg
ularly, since some materials, such as polymers, can creep under pressure.
Moreover, positioning the majority of the sample block within the clamp,
such that only the cutting tip extends, will increase stability.
Orientation of the sample to the knife edge can affect the
quality of the section. In the following description, a multilayer sample is
considered as a series of parallel lines that can be placed either vertically
or horizontally in a rotatable vise of a microtome with a horizontal knife
edge ( Fig. 3 . 1 8 ) . For most samples, the initial cut is best made with the
sample rotated 1 0 0 from vertical, with the most important layer closest
to the knife. Additionally, a corner of the trapezoid, rather than a flat
edge, should be cut first; this order minimizes stress on the block. Exact
vertical orientation of the layers can increase section curling and particle
loss, while exact horizontal orientation can result in the compression of
Figure 3 . 1 6
the sample. Depending on the sample and how it behaves during cutting,
An optimal embedment for microtoming,
the orientation may need to be changed.
with a small triangular sample positioned
at the tip of an embedment cone.
The standard procedure is to cut the multilayer sample with
the layers orthogonal to the knife edge . However, other orientations are
40
Chapter
3
/' /'
Sample embedment
First trimming step
--
Figure 3 . 1 7
The precise tri m m i n g angles required to
produce a trapezoidal tip for optimal
Second trimming step;
rotate 1 05°
Third trimming step;
rotate 1 05 °
microtoming. The trapezoidal shape is
placed i n the microtome vise, with the
parallel sides vertical (as shown) or
/
rotated slightly to the left, so that the
cutting blade, when stri king the block
from the botto m , will first cut into a
small corner, then progress to the rest
of the sample. This proced ure min imizes
stress on the knife as it cuts into the hard
polymer block.
Fourth trimming step;
rotate 85°
Close-up o f sample
in trapezoidal cut media
possible. Cartwright and coworkers placed the sample with the layers
parallel to the cut edge and produced slices of individual layers that were
then placed in a micro diamond cell for analysis ( Cartwright, Cartwright,
and Rodgers 1 977). Oblique sectioning is another method used in the
case of thin layers to increase their analysis width effectively ( Reffner
and Martoglio 1 99 5 ) . In this method, the sample is oriented such that
the layers are at an angle to the cutting edge ( Fig. 3 . 1 9 ) . As shown in
Reffner and Martoglio, an angle of 1 0° will increase the free width of a
1 0 /-Lm layer to nearly 53 /-Lm. Figure 3 .20 shows a sample from the var. nish layer of an eighteenth-century gilded table. The analysis question
was to determine the adhesive under the gilding. Since this layer was
Figure 3 . 1 8
The orientation o f sample layers and the
trapezoidal-trimmed tip for optimal micro
toming. The cut direction is from the bot
tom to the top, with the imaginary knife
edge aligned parallel to the bottom edge
of the page.
Horizontal:
creates compression
Vertical:
causes curl ing; the
sample may pop out
Angle offset:
optimum
Sample Col l ection and Preparation
R
*
I
II ", RI
"I ', ,,'�=::7Z.==27::=*=::7Z.=::"""'7
only about 1 0 /-Lm thick, the cross section was cut at an oblique angle to
increase the width for analysis.
The optimal sample thickness for IR transmission analysis
is 1 - 1 0 /-Lm (Derrick, Landry, and Stulik 1 99 1 ) . Sections thicker than
1 5 /-Lm usually absorb IR radiation too strongly to allow for analysis.
Moreover, an attempt to cut thick sections can result in a sample pop
ping out of the slice, in chattering of the knife, or in damaged knife
edges. When a microtoming problem occurs, it can often be solved by
slicing thinner sections ( 1 11m ) , then returning to slice a thicker section
(5-10 /-Lm) . All cuts should be smooth, slow, and executed with a motor
Figure 3 . 1 9
Two possible cuts for a m u lti layered
sam ple. Cutting a sample at an oblique
=
angle will in crease the effective analysis
width of the layer ( R
41
IR beam direction).
ized microtome, if available, set at speeds of 0. 1 -3 . 0 mm/sec. Cutting
speeds that are variable or too fast can cause particle loss and curling of
the thin section.
The optimum environment for microtoming is a small room
with no foot traffic, drafts, or temperature and humidity fluctuations.
The microtome should sit on a sturdy, vibration-free table. When cutting
problems occur, all sources of heat are suspect and should be modified
when possible. These heat sources include lighting, hand temperature,
and the human breath. If a motorized microtome is used, the microtome
and its bench should not be touched during the cutting stroke.
As the section is being cut, it can be encouraged to cling to
the knife. This technique can be performed with a small, stiff bristle
artists' brush ( size 000) that can be used to hold the initial cut edge
of the section to the knife surface without the sample region being
Figure 3.20
touched . An eyelash brush or a cat-hair brush will also work well. Static
A finish cross section from a gilded table
charge should keep the section on the knife. After the section is cut, it
sam ple. The photograph on the left shows
can be easily and delicately picked up from the glass surface with the
a thin section that was microtomed with
paintbrush. For IR analysis, sections are taken directly from the micro
the cut edge perpendicular to the top sur
tome, placed on an appropriate IR window, and transferred to the
face of the sample. The photograph on
sample stage of the IR microspectrometer. If necessary, folds or wrinkles
the right shows a thin section from the
in the section can be removed by the placement of another transparent
same sample that was cut at an oblique
window on top of the section. Alternatively, ethanol or heat may be
angle (45°) . The width of the top coating
used to relax the polymer, provided that the sample will not be
layer was increased significantly.
adversely affected.
42
Chapter
3
Summary
The ultimate goal of any analysis is to produce useful and reliable infor
mation about the sample. Critical steps toward that goal are the selec
tion, collection, and preparation of the sample. Errors at any point in
this process-such as selection of a sample that poorly represents the
obj ect or contamination of the sample through placement in a poor stor
age container-can produce analytical results that are, at best, recognized
as meaningless or, at worse, misdiagnose the object and its condition and
lead to inappropiate treatment decisions.
Additional Reading
Chal mers, J . M . , and M. W. Mackenzie
1 9 8 8 . Solid sampling techniques. In Advances in Applied Fourier Infrared
Spectroscopy, ed. M. W. Mackenzie. New York: John Wiley and Sons.
H umecki , H . , ed.
1 995. Practical Guide to Infrared Microspectroscopy. New York: Marcel Dekker.
Kri s h n a n , K . , and S. L. H i l l
1 990. FT-IR microsampling techniques. In Practical Fourier Transform Infrared
Spectroscopy, ed. J. Ferraro and K. Krishnan. New York: Academic Press.
Perkins, W. D.
1 99 3 . Sample handling in infrared spectroscopy-An overview. In Practical Sampling
Techniques for Infrared Analysis. Boca Raton, Fla.: CRC Press.
Chapter
4
Infrared Analysis Methods
Proper instrumentation-that is, a well-functioning spectrometer-is the
first step toward producing good IR spectra. The design, operation, and
maintenance of IR spectrometers, however, is beyond the scope of this
book. Resources for information on IR instrumentation are listed in the
additional readings at the end of this chapter. In particular, Low and
Baer clearly describe the interferometer design, along with the advantages
Fourier transform infrared ( FT-IR) spectrometers have over dispersive
instruments ( Low and Baer 1 977).
The second step toward the production of good spectra is the
selection of a suitable technique for presenting the sample to the spec
trometer. There are a wide variety of methods using accessories that fit
into the sample compartments of most spectrometers. The selection of
an appropriate analysis method depends on the type, form, and amount
of sample to be analyzed. No one method can meet the analysis needs
of all samples.
Theoretically, one material should give one, unique IR spec
trum that relates to its chemical composition. However, the physical state
of the sample, its preparation, and the analysis method chosen have an
effect on the resulting spectrum and can shift band positions, as well as
change band shapes and relative intensities. Figure 4 . 1 shows spectra for
Acryloid B-72 ( methyl acrylate-ethyl methacrylate copolymer) obtained
by four different analysis methods. Slight, but recognizable, spectral vari
ations are seen in these four spectra, because of their different analysis
techniques. Thus, while spectra are reproducible within each method,
caution must be used when spectra acquired from one technique are
compared to reference spectra collected through a different method.
This chapter focuses on the equipment, sample requirements,
spectral variations, and limitations of several of the most common analy
sis techniques. Transmission methods-in which the beam passes through
the sample-are used for the analysis of gases, liquids, and solids. Reflec
tion methods measure changes in the IR beam as it is reflected by the
sample; these methods are generally used for solid samples. Microspec
troscopy, often the best method for the analysis of small samples taken
from works of art, will be discussed in detail. Additionally, micro scale
versions of each method will be presented for use with limited amounts
of sample when an IR micro spectrophotometer is not available. Table 4 . 1
presents analysis methods described i n this chapter and their relationship
44
Chapter
4
Transmission
Attenuated total
reflection (ATR)
Diffuse
reflection (DRI FTS)
Figure 4.1
IR spectra of Acryloid
8-72
collected by
fou r different analysis methods. The over
all spectral pattern is similar, but slight
variations in band position and intensity
4000
3600
3200
2800
2400
2000
1 800
1600
1 400
1 200
1 000
800
600
Wavenumber (cm- 1 )
can be related to the analysis method.
to different sample types. In-depth information on the techniques
presented here, as well as on other techniques ( chromatographic, ther
mal, photoacoustic, and emission ) , can be found in the Additional
Reading section.
45
I nfrared Analysis Methods
Examples
Potential analysis methods
poll utant, fum igant
transmission gas cell
oil, paste, gel, curing adhesive,
plasticizer
fi l m on transparent window o r diamond cell, horizontal reflection
absorption, liquid i nternal reflectance cell
Nonviscous
solvent
liqUid ceil/liquid internal reflectance cel l , film on transparent win
dow, horizontal reflection -absorption
Solution
e m u lsion , varnish, paint,
consolidant (before curing)
diffuse reflectance , pressed pellet (dried residue), cast fi l m on
window o r reflective su bstrate, diamond cell, internal reflectance
plastic, glass
external reflection, grind for K B r pellet, section for transmission o r
reflection-absorpti o n , f i l m o n transparent window o r diamond cell
Hard
(rough)
ceramic, sto ne, corroded metal
diffuse reflectance, grind for KBr pellet, section for transmission or reflection-absorption, fi l m on transparent window or
diamond cell
Soft
flexible polymer, adhesive,
paper, parch ment
dissolve in solvent and recast as thin fi l m , internal reflectance,
fi lm o n transparent window o r diamond cel l , reflection -absorption
Sample form
Gases
Non reactive gas,
gas mixture, trace
atmospheric
components
Liqu ids
Viscous
Solids
Hard
(smooth)
o n mi rrored su bstrate
Thin film
plastic fi l m
dissolve in solvent and recast as thin fi l m , internal reflectance, film
on transparent window o r diamond cell, reflection-absorption on
m i rrored su bstrate
Coating
coated paper, coated metal,
adhesive
dissolve in solvent and recast as thin film internal reflectance, film
on transparent window o r diamond cel l , external reflectance
Fiber
fabric, fur, carpet, polymer, wood
diffuse reflectance, internal reflectance, film on transparent w i n
d o w o r diamond cell
Powder
m i neral, colorant, clay, stone,
corrosion product
diffuse reflectance, grind for KBr pellet, internal reflectance, film
on transparent window o r d iamond cell
Table 4.1
Infrared Transmi ssion Measurements
I R analysis methods for various types of
samples. Each tech n i q ue may also be per
Until thirty-five years ago, transmission measurement was the only
formed on microsamples.
method of IR analysis. Because of its versatility, IR transmission was
used for both qualitative and quantitative analysis of gas, liquid, and
solid samples. Large libraries of spectra from IR transmission analyses
were produced. Thus, IR transmission spectra became a standard that is
still used today and against which spectra generated from other analysis
methods are compared.
One advantage of transmission analysis is that the total sample
absorption is proportional to the thickness of the sample (pathlength) and
its concentration. This correlation establishes a simple relationship for
quantitative calculations. Also, because of high energy throughput, trans
mission analysis methods have greater sensitivity than reflection analysis.
The character of a transmission spectrum is dependent on
sample preparation, particle size, and absorptivity. For example, spectral
distortions, such as band broadening, occur when the transmitted beam
is partially reflected or refracted ( Fig. 4 .2 ) . Additionally, whenever
another material is added to the sample, either to dilute it or to support
Chapter
46
4
it, there is an added risk of contamination, which can result in spurious
Transmission
absorption bands. Some common spectral anomalies and solvent bands
seen with transmission spectra are listed in Table 4.2. Many of the dilu
ents mentioned in this table are no longer common in IR analysis labs;
however, they may still be encountered in published reference spectra
because of their previous high incidence of use.
Infrared window materials
For transmission analysis, the sample can be placed freestanding in the
IR beam, or it may be held in place by a supporting material. Ideally, the
supporting material would not, in itself, absorb any of the IR radiation.
Refraction
While many materials come close to this ideal, each has its own limita
tions regarding frequency range and chemical compatibility. The selection
of the support material is dictated by the character of the sample and
analysis method. Table 4.3 lists the common types of support materials
used, their useful frequency ranges, refractive indices, and chemical
compatibilities.
While glass is a good support for the visual examination of
samples, it absorbs strongly over most of the mid-IR region. Figure 4 . 3
shows the IR spectrum of a standard glass microscope slide, as well a s
the characteristic spectra of two materials, potassium bromide ( KBr) and
barium fluoride (BaF2 ) , commonly used as IR windows in the mid-IR
region. The glass slide essentially absorbs all the IR radiation from
2200 to 400 cm-1. Since the main property desired for IR window
Reflection
material is its transparency to the IR radiation emitted by the source,
glass is not used as a support material for IR analysis.
Many IR transparent materials are available for use as IR
window materials; each one has certain advantages and disadvantages,
and it is up to the analyst to select the material most suited for a particu
lar experiment. The relatively inexpensive KBr and sodium chloride
(NaCl) windows are commonly used. The KBr and NaCI windows are
Figure 4.2
A radiant beam path when the beam is
transmitted, refracted, and reflected by a
sample and/or substrate ( n A
=
refractive
index of air; n s = refractive index of the
material).
useful over the entire mid-IR region, but are moisture sensitive and will
dissolve in water. Thus, the use of aqueous solutions must be avoided.
Moreover, KBr and NaCI pellets, if left in humid air, will fog and become
pitted. These windows are, therefore, typically kept in a desiccator. Also,
NaCl and KBr windows are easily scratched and gouged, so that the
requirement for routine cleaning and polishing makes it hard to maintain
the original level of transparency. Poor window surface quality and trans
parency are particular problems in microspectroscopy-both during the
process of aperture positioning as well as at the photodocumentation step.
BaF2 windows are not attacked by water. Therefore, they can
be stored in the open, and aqueous solutions can come in contact with
the material without dissolution. Also, because the windows are very
clear, they provide high-quality imaging for light microscopy and
photodocumentation. However, BaF2 windows are roughly four times as
expensive as KBr windows. While they can be readily cleaned and pol
ished for reuse, they are also very fragile and will break when dropped
even a few inches. Finally, these windows have a cutoff at 700 cm- 1 and
47
I nfrared Analysis Methods
Sample preparation method
Problems and causes
Remedies
Free film
interference fringes from
shiny sample surfaces
abrade the sample surface o r analyze by another method
bands totally absorbing from
a too-thick sample
make sample thinner by flattening o r cutting
bands totally absorbing from
a too-thick sample
make sample thin ner by flatten i n g o r cutting
curved or slanting baseline
due to n onflat sample surface
flatten sample o r place i n a compression cell;
avoid particle edges
Dissolved in carbon
tetrachloride (CCI4)
interfering bands at 700-800,
980, 1 2 50, 1 550 cm- 1
due to solvent
use only for 4000-1 350 cm-1 range
Dissolved in carbon
disulfide (CS2)
interfering bands at 1 400-1 650,
2 1 50 , 2300 cm-1 due to solvent
use only for 1 3 50-650 cm- 1 range
Diluted with N ujol
(mineral oil)
interfering C-H bands (2850-2960,
1 460, 1 3 80, 720 cm-1 ) due to dil uent
use only for 1 3 00-200 cm- 1 range
Dil uted with Fluorolube
(fluorocarbon oil)
interfering bands at 1 080-1 200,
965, 900 cm-1 due to diluent
use only for 4000-1 300 cm-1 range
Grou nd and diluted
with KBr, Csl, AgCl,
then pressed into pellet
salts are hygroscopic; may absorb
water with interfering bands at
3400, 1 640 cm-1
grind and mix sample and salt in dry atmosphere and/or
under heat lam p
Film, liquid, or particles
placed on a support
may contain sharp N0 3
at 1 3 84 cm- 1
=
band
use only fresh salt supply and store in dark contai ner
Table 4.2
thus may not be appropriate for the identification of some inorganic
Possible spectral anomalies d ue to the
materials with characteristic absorptions that occur at lower energies,
Silver chloride (Agel) windows are also water insoluble. They
sample preparation method.
have good transmission properties from 4000-400 cm- I, are relatively
inexpensive ( only twice the cost of KBr) , and are fairly durable. These
windows, however, are sensitive to light and will darken upon exposure
to short wavelength visible light-therefore, they must be kept in the
=
dark. For IR microspectroscopic analyses, their relatively high refractive
index (n
2.00) may affect focusing and sample isolation.
While the most commonly used window size for an IR salt
x
plate is a 13 mm diameter disk of 2 mm thickness, some instruments
x
have sample holders specifically designed for small (6
(32
1 mm) or large
2 mm) salt plates. Windows can be found in a 4 mm thickness, but
these tend to decrease the available energy in the low-wavenumber end of
the usable window region and may actually cut off 5 0- 1 0 0 cm- 1 higher
than the 2 mm window. Windows of 1 mm thickness can be specially
ordered. These will have better transmission properties than the 2 mm
thick variety and therefore may be desirable for some situations. They
are likely to be more expensive, though, and are substantially more frag
ile than the 2 mm thick windows.
In normal use, IR windows may become fogged or scratched
or accumulate insoluble deposits. When this happens, the surface can be
reconditioned by being polished with fine-grain emery paper. The coarse
ness of grit selected for the initial polishing depends on the extent of the
damage. Polishing kits from many of the IR supply companies have a
Chapter
48
4
Material
Range (cm - ' )
Refractive
index
Compatibility
Glass
55,000-3000
1 .45
water insoluble, attacked by hydrofluoric acid
Quartz
40,000-2500
1 . 54
water insoluble, attacked by hydrofluoric acid
Sapphire
20,000-1 780
1 .7
good strength, no cleavage
Diamond
40,000-200
except 2500-1 800
2 .42
insolu ble, inert, hard, expensive
Calcium fluoride
70,000-1 1 1 0
1 .43
water insoluble, does not fog, incom patible with ammon i u m salt
solutions
Barium fluoride
1 . 47
65, 000-700
water insoluble, does not fog, breaks easily, incompatible with
ammonium salt solutions
Zinc selenide ( i rtran IV)
2 .49
1 0 ,000-550
water insoluble, resistant to most solvents, brittle, sli ghtly soluble
in acids
Sod ium chloride
40,000-625
1 . 54
hygroscopic, fogs slowly, easy to polish, low cost, water soluble
Silver chloride
25,000-400
2 .07
water insolu ble, very soft, sensitive to light
Potassium chloride
40,000-500
1 .49
hygroscopic, fogs slowly, easy to polish, water soluble
Potassi u m bromide
40, 000-400
1 . 56
hygroscopic, fogs with moisture slightly faster than NaCI; softer
than NaCI
KRS-5 (Thallium iodidebromide, TI 2 I B r)
1 5 ,000-250
2.38
water insoluble, toxic, soft, soluble i n bases
Cesi u m bromide
1 0,000-250
1 . 66
hygrosco pic, soft
Cesium iodide
1 0,000-200
1 . 79
hygroscopic, soft, fogs slowly
Teflon (th in film)
5000-500,
except 1 200-900
1 .5 1
inert, u naffected b y any solvent, avai lable a s disposable cards
Polyethylene (thin fil m )
4000-30, except
3000-2800, 1 4601 3 80 and 730-720
1 . 53
water insoluble, resistant to most solvents, very soft, difficult to
clean, available as disposable cards
Table 4.3
good selection of fine-grain papers, generally ranging from 400 to 1 200
I R transmission ch aracteristics of support
grit. The grinding process is performed with emery paper wetted with
materials.
alcohol and moved in a figure eight motion. The figure eight is necessary
to prevent the flat crystal from becoming convex. It is usually necessary
to use only one or two strokes with each grade of paper. For final polish
ing, a cloth-lap procedure is used ( Chicago Society for Paint Technology
1 9 8 0 ) . For this technique, a soft, lint-free cloth is stretched tightly and
fastened over a thick flat surface, such as a piece of glass. A small
amount of very fine polishing agent ( 0 . 5 !-Lm or less) is placed on one
area of the cloth and wetted with a little solvent ( or, for salt plates, with
alcohol ) . The crystal to be polished is swept in the figure eight motion
until it appears clear and smooth. Then the crystal is placed on a clean,
dry area of the cloth and slid across in a straight motion to gently dry
and clean its surface. To determine whether the crystal is still flat, it
may be placed on an optically flat piece of glass and illuminated with a
sodium vapor lamp to be examined for fringes: fewer fringes indicate a
flatter crystal. Plastic gloves should be worn during the polishing process
to keep finger oils and moisture from affecting the window and to pro
tect the polisher's hands from hazardous materials. ( For more polishing
methods, see Smith 1 979: 1 1 5-1 7; for polishing methods for micro size
KBr pellets, see Teetsov 1 99 5 . )
49
I nfrared Analysis Methods
Glass microscope slide
Q)'"()
.=if.
c
<1l
E
C/l
c
<1l
4000
3200
3600
2800
2400
2000
1 800
1 600
1 400
1 200
�.=if.()E
1 000
800
600
800
600
Q)
c
KBr
C/l
c
<1l
3600
4000
,
,,
,••,
,
Q)'"()
.=if.
C
<1l
E
C/l
C
<1l
Figure 4.3
I R spectra of glass (1 m m thick), potas
sium bromide, and barium fluoride sub
strate materials. The I R tran smission range
3200
4000
•
3600
2800
2400
2000
2800
2400
1 600
1 400
1 200
1 000
,•·, ,, ,•, ,• ,,
,
,
•
•
,
•
·
,, • • ,,•·
,•, ,• ·•, ,, •, •,•
•, •
,•,
·••
,,• •,·• •,•,
,•, •, •,, •,• ,•
, , , , ,.
3200
1 800
·
BaF2
•
2000
1 800
1 600
1 400
1 200
1 000
800
600
Wavenumber (cm- 1 )
is shown.
Most IR windows should be stored in a dry atmosphere to
protect them from moisture. Desiccators and low-temperature ovens are
available for this purpose. When limited amounts of sample are avail
able, it is sometimes prudent to save the sample on or in a pellet for
later reanalysis. Sample holders can be used to label and store pellets
for later use.
50
Chapter
4
Transmission analysis of gases
Materials that are in the gas phase at room temperature may be analyzed
as a gas or condensed in a cold trap with liquid nitrogen and analyzed as
a liquid or solid. Gas-phase molecules rotate freely, producing very sharp
rotational absorption bands that are not seen in the liquid or solid-phase
spectra for the same sample (as shown in Fig. 2 . 4 ) . These bands are very
characteristic, though, and are often used for the identification and quan
titation of components in a gaseous mixture. For quantitative analysis of
a gas, its absorbance is proportional not only to its concentration and to
the IR path length but also to its pressure. High pressures can, however,
result in absorption band broadening.
A gas cell consists of a glass or metal cylinder fitted at each
end with a transparent, nonreactive IR window ( Fig. 4 . 4 ) . The cell has
two stopcocks for evacuation and filling. The windows must be well
sealed during assembly to prevent leakage. The typical cell is single pass
and 10 cm long, though other pathlengths are available. A multiple
pass cell contains mirrors on its ends to reflect the beam back and forth
through the sample several times before passing it on to the detector.
This increases the effective optical pathlength and thus increases the
absorbance and sensitivity of the measurement, allowing the detection
of concentrations in the parts-per-million range. Gas cells with reflections
of 40- 1 0 0 times, producing pathlengths up to 1 2 0 m, are available.
Miniature, variable-temperature, flow-through gas cells can
be used to identify the small amounts of a gas-phase material obtained
from the effluent of a gas chromatograph ( GC ) or thermal analyzer.
Alternatively, a unique GC-IR interface, in which the gas-phase effluent
from the GC is frozen onto an IR transparent window cooled to liquid
nitrogen temperatures, was developed by Fuoco, Shafer, and Griffiths
( 1 9 8 6 ) . The window is then rotated into the IR beam to obtain spectra
of the condensate fractions.
Transmission analysis of l iquids
Solution spectroscopy-that is, spectroscopy of liquids or solids in solu
tion-has the advantage of being highly reproducible. Problems and spec-
Figure 4.4
A single-pass, I R gas cell ( 1 0 em). I R
transparent windows at each end of the
cell allow the passage of IR rad iation
beams.
I nfrared Analysis Methods
51
tral artifacts due to sample preparation (heat, pressure, and particle size)
are rarely encountered.
Liquids generally require very little sample preparation. A
nonvolatile liquid sample can be spread as one drop on a single salt plate
( BaF2 is nonreactive to most liquids) or other transparent surface, such
as a single surface of a diamond cell. However, unless they are applied
to the support as very thin films, most liquids absorb too strongly; the
result is spectra with some absorption bands having less than 1 0 % trans
mittance. If this is the case, the sample must be diluted with a solvent.
Carbon tetrachloride and carbon disulfide solvents were commonly used
as diluents in IR spectroscopy because they themselves have few interfer
ing IR absorptions. These diluents are rarely used today because of their
toxicity and because of the availability of alternate IR analysis methods.
Volatile liquids can be analyzed by use of a commercial liquid
cell or simply by sandwiching a drop between two salt plates. Commercial
liquid cells consist of two IR transparent windows wedged together in a
metal frame. The cavity for holding the solution is either a drilled space in
one of the windows or a space created by a gasket of known thickness
between the two windows. The spacers are typically made of Teflon or
lead; the spacer thickness controls the pathlength and capacity. For quan
titative analysis of a liquid, absorbance is proportional to both concentra
tion and cell pathlength.
Sealed and unsealed liquid cells are available ( Fig. 4 . 5 ) . For
cleaning, a permanently sealed liquid cell is flushed thoroughly with sol
vent, then dried with a stream of nitrogen or clean, dry air. Nonsealed,
or demountable, liquid cells can be cleaned after disassembly. The
demountable cells provide flexibility in changing the IR windows as they
become clouded or scratched. However, since these demountable cells
have the potential to leak, they are best used for viscous liquids or mulls.
Micro liquid cells are available for the analysis of small sample volumes
( 0 . 5-50
f..LI ).
Other specialty cells, such as variable-temperature, variable
thickness, and flow-through cells, are also sold. Liquids can also be ana
lyzed by some reflection methods, such as diffuse reflection (DRIFTS)
and internal reflection (IRS ) .
Figure 4.5
Single-reflection and micro liquid I R cells.
For both types of holder, the cell is sealed ,
and then the liquid is injected with a
syringe. The cells can be d isassembled
for cleaning.
52
Chapter
4
Transmission analysis of solids
Several methods can be used for the IR transmission analysis of solid
samples. In the most commonly known method, the samples are pow
dered, then mixed with an IR transparent material, such as KBr, and
pressed into a clear pellet for analysis . In other methods, samples are
analyzed as free, or unsupported, films or as thin films flattened or
deposited on a transparent window. The deposition of films on a support
is a highly versatile technique that has become the primary method used
for samples analyzed with IR microspectrophotometers. Even hard and
tough materials can be compressed by use of a diamond cell for transmis
sion studies. Examples of materials that may be analyzed by these IR
methods are viscous or nonvolatile liquids ( oils, adhesives), films dried
from a solution (varnishes, paints, emulsions), and flattened, solid samples
(particles, pigments, fibers, scrapings ) . A disadvantage to the transmis
sion analysis of solid materials is that grinding, dissolution, melting, or
flattening is usually required. Any of these procedures can produce
changes in sample orientation or in crystalline structure; the result is a
slightly altered spectrum.
Pellets and micropellets
The pressed-pellet technique for IR analysis was first introduced in 1 952,
and it was used as the primary method for the analysis of solids for over
two decades ( Stimson and O'Donnell 1 9 5 2 ) . It is still a commonly used
technique because it requires no expensive instrument accessories, it
allows for control of analyte concentration, and it results in a sample
that may be conveniently stored for later reanalysis. Butz's text on IR
absorption analysis of powdered samples is recommended as a good
basic reference, since it gives detailed information on the preparation and
problems of preparing salt pellets (Butz 1 96 0 ) . The analysis of small
samples with KBr micro pellets has been successfully applied to early
microphotographic emulsions (Newman and Stevens 1 9 77), artist paint
materials (Newman 1 9 80; Meilunas, Bentsen, and Steinberg 1 99 0 ) , and
furniture finishes ( Derrick 1 9 8 9 ) .
The standard pellet size for commercial dies i s 1 3 mm.
Micropellet dies can produce disks of 0.5 or 1 .5 mm in diameter. For
analysis, a sample pellet is placed in a pellet holder and inserted directly
into the sample compartment of the IR spectrometer. A background
scan is usually taken with no pellet in the IR beam path. Micropellets
require a beam condenser unit that focuses the energy of the beam to the
x4
correct size and position of the sample. Figures 4 . 6-4 .9 show pellet dies
and holders for both the normal and the micropellets, along with a
beam condenser.
Beam condensers allow micrograms of samples to be ana
lyzed, because they focus the radiation to a smaller diameter, thereby
maximizing the amount of the energy in a minimum size area. The beam
condenser must be aligned when placed in the sample chamber with both
the pellet holder and empty pellet in place, to ensure that the beam will
pass through the pellet area. Most instruments have a white light source
that can be used for the rough alignment of the mirrors in sampling
I nfrared Analysis Methods
53
accessories when needed. Turning out the room lights increases the visi
bility of the alignment beam. A white card or piece of paper can be
inserted at each position to locate the beam and to ensure that the focal
point occurs at the pellet position. Final alignment is done by optimizing
the IR beam intensity at the detector. The pellet and its holder must be
Figure 4.6
A 1 3 m m pellet die (top center) and hold
ers. A sample is ground into fine particles
and mixed with an alkali halide salt i n the
mortar and pestle, then transferred to the
pellet die and pressed into a transparent
pellet.
Figure 4.7
A standard sample holder with accessories
for 1 3 mm pellets and thin fi lms. The stan
dard holder fits into the sample compart
ment of the IR spectrometer.
Figure 4.8
A micropellet die (1 . 5 mm) and holder.
Sample preparation for micropellet analysis
requires small tools and an extra-small
mortar and pestle.
54
Chapter
4
Figure 4.9
A beam condenser (x4) shown with a
micropellet at the center focal point. The
beam condenser may also be used with
the internal reflection holder and the micro
liquid cel l .
repositioned in exactly the same manner each time, with the entrance
face always oriented in the same direction. It is important to recheck
alignment with the sample in place, since the sample itself may slightly
change the focal length of the beam. If a spectrum with a low signal-to
noise ratio is obtained, the first thing to check is the position of the beam
relative to the pellet.
To prepare a pellet, a small amount of sample is first placed
in a clean agate mortar and ground with a pestle to produce particles
that are smaller than the wavelength of IR radiation (5 fLm ) . To deter
mine when the sample is ground finely enough, use the pestle to form a
smear on the mortar; the sample should feel slippery, should have no
grit, and should spread out in a waxy film. For pulverizing large numbers
of samples, a stainless steel ball mill or vibrator-grinder ( see Suppliers,
Wig-L-Bug, Crescent Dental Manufacturing Co. ) can minimize the
tedium. Heat and pressure produced by excess grinding, however, can
cause changes in some samples. As with the mortar and pestle, all grind
ing containers should be thoroughly cleaned between samples to prevent
cross contamination. Some tough, hard samples-such as epoxy resins,
paper, parchment, and rub ber-are very difficult to grind. Adding a few
drops of liquid nitrogen to the sample will freeze it before crushing, thus
making it brittle and easier to grind.
After the sample is ground, it is uniformly mixed with a pow
dered matrix, such as an alkali halide salt, that has a broad window of
transparency in the mid-IR region. While potassium chloride (KCI), KBr,
cesium bromide, cesium iodide, AgCl, and polyethylene have all been
used to press pellets, KBr is the most commonly used. When KBr is used,
it is important to mix quickly, as KBr is hygroscopic and will pick up
water for the atmosphere that will appear in the resultant spectrum as
broad bands at 3450 and 1 65 0 cm- 1 • Preparing the samples under a
strong incandescent light or heat lamp can slow water absorption.
The mixed matrix is transferred to a pellet die and spread
evenly. Then the plunger portion of the die is inserted, twisted, and
lightly tapped against the sample to ensure that the sample is distributed
I nfrared Analysis Methods
55
evenly within the die. An uneven distribution of the salt matrix will pro
duce a pellet with cloudy areas. The surfaces of the stainless steel dies are
highly polished mirrors that produce transparent faces on the pellet and
thereby minimize scattering effects. It is important that the die surfaces
are clean and not scratched. They should not be touched with fingers and
should be cleaned thoroughly between samples and before storage to
minimize chances for corrosion.
After loading with the sample, the die is usually attached to a
vacuum line and evacuated for a few minutes with a high vacuum pump.
This procedure removes water, solvents, and air from the mixture and
results in a clearer and longer-lasting pellet. The die is then compressed
under several thousand pounds of pressure, either by hand or by a
hydraulic press. After the pressure is released, the die is opened, and
the sample pellet is carefully removed with plastic forceps. The sample
should be immediately transferred to a pellet holder in the instrument for
analysis. For analysis at a later time, the pellet must be stored in a water
free environment, such as a desiccator, a low-temperature oven, or a
purged IR bench.
A pellet may also be prepared from a sample dissolved in a
volatile solvent: a few drops of the solution can be placed on some pow
dered salt; once the solvent has evaporated, the solute is mixed with the
salt powder, then pressed into a pellet. Any residual solvent, however,
will hinder the production of a clear pellet. Microsamples dissolved in
a solvent can be drawn up and concentrated into the tip of a KBr cone
commercially available as a Wick-Stick ( see Suppliers, Perkin-Elmer
Corp . ) . The tip of the cone is broken off, ground, and pressed into a
micropellet. A solvent blank pellet should be run alongside any sample
to check for potential contamination and impurities.
Micropellets containing only a few micrograms of sample
may also be prepared. With small samples, extraneous absorptions due
to contaminants can appear aS' strong as absorptions from the sample.
Therefore, it is critical to ensure that clean techniques are used. One
method for preparing tiny, irreplaceable samples is to do all grinding,
mixing, and transferring inside a glove bag that is slowly purged with
dry air or nitrogen. This method will minimize moisture pickup, as well
as other sources of environmental contamination.
Most solid samples can be analyzed as pellets, but some
problems may result. Nonhomogeneous samples, such as a paint cross
section, will be homogeneous after grinding. Since individual components
of multicomponent mixtures can be difficult to identify from an IR spec
trum, a preseparation method should be used when feasible. Grinding
some samples can cause changes in crystallinity. When particles are not
ground finely enough in a pellet, some scattering of the beam may occur,
resulting in energy loss and a broadening of the absorption bands. The
sample spectrum should always be examined for potential absorption
bands due to the pellet matrix, such as water absorption, contaminants,
or even reaction products ( for example, some organic acids can react
with alkali halides).
56
Chapter
4
Unsupported films
Self-supporting materials, such as films, fibers, and tapes, can sometimes
be mounted directly in the path of the IR beam without the aid of a sup
porting material; in this way problems of contamination and interfering
bands are avoided. The only sample preparation is mounting the sample.
A holder should maintain the sample at the focal point of the beam with
out blocking the beam. Commercially available magnetic film holders
easily hold a large sample. Other sample mounts, such as pellet holders,
can often be converted for use by stretching the sample across the empty
pellet opening and holding it in place with tape.
While easily prepared and analyzed, freestanding samples
can be difficult to analyze. A sample that is sturdy enough to be self
supporting is often too thick and absorbs too strongly, producing satu
rated spectral bands. Samples that are not flat, such as fibers, can cause
the radiant beam to scatter. Scattering can be reduced by applying min
eral oil to the sample (if the hydrocarbon band region is not critical) or
by flattening the sample.
Free film samples can produce interference fringes. Inter
ference fringes are the result of internal reflections of the IR beam inside
the sample. Interference fringes are seen as a sinusoidal wave superim
posed on the sample's molecular absorption pattern ( Fig. 4 . 1 0 ) . The
intensity of the wave is a function of the refractive index of the sample
and the glossiness of its surface. The frequency of the wave is dependent
on the wavelength of the radiation, as well as on the thickness of the
sample film. In fact, counting the fringes is an accurate method for the
calculation of film thickness; the equation shown in Figure 4 . 1 0 is used
(Harrick 1 9 7 1 ) . The fringes can be minimized by abrading the sample
surface, by using polarized incident light along with an off-axis entry
angle of the beam, by sandwiching the sample between two pellets or
diamond surfaces, by coating the sample with an oil, or simply by ana
lyzing the sample by another method, such as internal reflection.
Films on transparent supports
Most solid samples can be cast, melted, pressed, or spread into thin films
for transmission analysis, but they require a supporting surface in order
to place and maintain them in the path of the IR beam. The support is
typically an IR-transparent material or window, such as a halide salt pel
let. Another type of support, disposable IR cards ( see Suppliers, Spectra
Tech, Inc., 3M films ) , has recently been introduced. These cards contain
a thin polymer film ( either Teflon or polyethylene) stretched on a card
board holder.
The analysis of a thin film of solid material on an IR window
is one common method used for IR microanalysis. This method has the
advantage that the sample can be prepared in a horizontal orientation on
the support material and can then be moved onto the sample stage with
out further disruption or transfer. Films may be prepared from samples
in many forms-that is, solutions, powders, or chunks.
Solutions of solid samples in volatile solvents (e.g., emul
sions, varnishes, and paints) , as well as some viscous liquids (e.g., oils ) ,
57
I nfrared Analysis Methods
Ql
o
c
Figure 4 . 1 0
An interference fringe pattern obtained
from a free film of polystyrene. The
equation
t =
---
.�E'"'"
<n
c
�
<fI.
1 0n
2 R I (V -V2)
1
may be used to calculate the thickn ess of
the fi lm (n = n u mber of oscillations; v =
1
starting waven umber [cm - 1 ] ; v2 = ending
waven umber [cm - 1 ] ; t = fi lm thickness in
m m ; and RI = refractive i ndex) .
4000
3600
3200
2800
2400
2000
1 800
1 600
1 400
1 200
1 000
800
600
Wavenumber (cm- 1 )
can be cast or spread onto the surface of a transparent window and dried
into a thin film. The liquid is drawn up into a capillary pipette and
dripped onto the surface of the window. Thick liquids may need to be
spread thinly and evenly over the surface by use of the pipette horizon
tally as a draw-down edge or by pressing another pellet on the sample
and compressing. The ideal sample should have a uniform thickness over
the analysis area. For macrosamples, the area of analysis may cover the
x
entire salt pellet, while for samples to be analyzed on a microspectrom
eter, the area of analysis may be only 1
1 mm or less. Thus, when a
1 3 mm window for microanalysis is used, multiple samples may be
placed on one window. It is important, however, that the liquid samples
not overlap and mix. The viscosity and surface tension (flow) of each
liquid sample may be checked by observing a drop of the sample on a
microscope slide prior to placing a microdrop on the sample window.
Dispersion of particles in an oil mull is a method that has
been used for years in IR analysis. Particles are ground finely as for pel
lets, then mixed with either a mineral oil (Nuj ol) or a fluorinated oil
( Fluorolube ) . Since these oils absorb in separate portions of the IR spec
tral regions, a sample is usually split into two portions, and half is mixed
with each type of oil. The mull is spread as a thin film on a salt pellet for
analysis. The mineral oil mixture gives a spectrum of the fingerprint
region, while the fluorinated oil mixture provides a spectrum for the
functional group region. Because this method is time-consuming and does
not have any clear advantage, it is now rarely used, and alternate meth
ods of analysis are preferentially selected.
Some polymers and waxes may be melted and then spread as
thin films on IR windows. The sample is placed on a glass slide, metal
plate, or tip of a metal spatula, then heated gently on a hot plate. The
melted sample is spread quickly on the window in a thin, even film and
58
Chapter
4
allowed to cool. Another method melts and cools the sample on a metal
plate, then analyzes it by reflection-absorption ( Fischer and Bader 1 99 4 ) .
Particles a n d fibers may b e flattened o r pressed t o form a thin
film. The sample is placed on a hard surface, such as a reflective metal
or IR window. It is compressed with a flat surface, a metal probe, or a
metal roller. A sample flattened directly on a transparent window can be
analyzed by transmission, and a sample flattened on a metal surface can
be analyzed by reflection-absorption. Soft samples flatten readily and
retain their shape. More difficult samples-such as fibers, adhesives, or
elastomers-may be placed between two transparent windows, flattened,
and held in place by a compression cell. The presence of windows on
each side of the sample will decrease any scattering effects resulting from
a nonflat sample surface. However, an increase in the total thickness of
an IR window ( caused by the two windows) will decrease the energy
reaching the detector. If this is a problem, two 1 mm thick windows can
used instead of the normal 2 mm windows. An alternative procedure is
to mix the sample with a small amount of a nonabsorbing matrix mater
ial ( such as KBr) and then to flatten the mixture as described above
( Reffner and Martoglio 1 99 5 ) . This procedure essentially forms a minia
ture pellet that increases the sampling area, minimizes scattering, and
makes the sample easier to transfer with a metal probe or razor blade.
Films on diamond cells
Salt windows can break and scratch when the samples are hard or non
compressible (e.g., minerals, epoxies) . In 1 95 9 the diamond anvil cell
was first introduced by Weir and coworkers ( 1 96 0 ) . The high pressure,
hard surface, and inertness of the diamond cell allowed reactive, opaque,
hard, or rubbery samples to be converted to thin films for IR analysis. It
also eliminated the potential for contamination due to an added matrix
and allowed the sample to be retrieved for additional analyses. The use
fulness of the diamond cell for the analysis of small art and archaeologi
cal samples was demonstrated in the 1 970s by scientists at the Canadian
Conservation Institute (McCawley 1 9 75; Laver and Williams 1 97 8 ) .
Forensic spectroscopists have also applied diamond cells t o the analysis
of tiny paint chips ( Rodgers et al. 1 976 ) .
The diamond anvil cell consists of two industrial-grade dia
monds, each with a flat, polished face, that are carefully aligned in a steel
compression cell. The diamonds serve as windows, on which the sample
is placed and through which the IR beam travels. The sample, preferably
a homogeneous particle, is placed on the clean diamond facet, the oppos
ing diamond is positioned on top, the cell is closed, and pressure is
applied to flatten the sample. The original high-pressure diamond anvil
cell is generally used with a x4 or x 6 beam condenser in which the
whole device-diamonds with compressed sample-is placed in the
sample compartment for IR analysis.
The newer, low-pressure, miniature diamond anvil cell ( see
Suppliers, High Pressure Diamond Optics, Inc.; Fig. 4 . 1 1 ) and the
micro diamond compression cell ( see Suppliers, Spectra-Tech, Inc . ) are
micros amp ling devices that can either be placed directly on the stage of
59
Infrared Analysis Methods
Figure 4 . 1 1
A m i n iature diamond com pression cell.
Samples are compressed between the
1 .5 mm diamond surfaces. Samples may
be analyzed with the cell halves together
or separate.
an IR micro spectrophotometer or used with a beam condenser.
Commonly, the two halves of the cell are separated after sample com
pression, and one facet containing the flattened sample is placed directly
on the analysis stage. Soft or thin samples can be placed directly on a
single facet and analyzed with or without the compression step. Liquids
may be analyzed on a single surface of the cell but should not be com
pressed, as they are readily displaced.
After analysis, the sample may be removed from the diamond
facet with a cotton swab or even with a scalpel, since there is no danger
of scratching the diamond. However, solvents should not be used to
clean the diamond, since the diamonds are held in place with an adhe
sive. Solvents may loosen the adhesive, resulting in misalignment or loss
of the diamond. If misaligned, a diamond face may scratch or break its
opposing surface.
As noted in Table 4 . 3 , diamonds are not transparent over the
entire mid-IR region. However, the main region of absorption is from
2500 to 1 8 00 cm- I , where few IR absorption bands occur. Also, com
plete absorption does not occur with the thinner diamonds used in the
smaller microsample diamond cells; thus the normal ratioing of a back
ground spectrum to the sample spectrum will eliminate the diamond
absorption bands. High pressures applied to the sample with a diamond
cell may induce pressure- and temperature-dependent phase transitions in
the sample ( Lippincott et al. 1 96 0 ) . However, it has been pointed out
that only minimal pressures are usually needed to spread the sample
evenly between the diamond faces, thus minimizing potential spectral
alterations ( Ferraro and Basile 1 9 79 ) .
Fibers
IR spectroscopy is very useful for the characterization of natural and
synthetic fibers. It is a standard analysis method used in the textile indus
try (Wannemacher 1 9 80; Berni and Morris 1 9 84 ) , as well as for the
analysis of leather, wood, and cellulose (Hergert 1 9 7 1 ; Liang 1 9 72 ) .
x
Internal reflection techniques work well for the analysis of larger
samples, such as fabrics (20
45 mm), yarns, or fibers ( at least 20 mm)
(Wilks and Iszard 1 9 6 5 ) . Very small samples of archaeological fibers and
dyes have been analyzed by IR microspectroscopy ( Lang et al. 1 9 8 6 ;
60
Chapter
4
Matsuda and Miyoshi 1 9 89; Jakes, Katon, and Martoglio 1 990;
Martoglio et al. 1 990; Jakes, Sibley, and Yerkes 1 99 4 ) . IR micro spec
troscopy is also standard for the identification of trace fiber evidence in
forensic examinations ( Cook and Paterson 1 97 8 ; Bartick 1 9 8 7; Tungol,
Bartick, and Montaser 1 9 9 1 , 1 99 5 ) .
Fiber, hair, and brush samples require little sample prepara
tion. Such a sample may sometimes even be analyzed "as is" by taping
the ends of a single fiber to hold it across a hole in a metal disk or sim
ply by laying it on an IR window (Tungol, Bartick, and Montaser 1 99 5 ) .
However, the fiber is often too thick and absorbs too strongly for direct
transmission. In this case, one alternative is to use a reflection method,
such as diffuse reflection or internal reflection.
A second alternative is to make the fiber thinner. The advan
tages to flattening a fiber are twofold. First, the horizontal measurement
area of the fiber is increased. Second, its surface becomes planar. The use
of the diamond cell is a quick and easy method for flattening fibers .
Another method is to press the sample between two IR transparent win
dows in a compression cell. A final option is to use a scalpel to slice a
thin section from the end or side of the fiber. This method is sometimes
preferred for the examination of the fiber structure, since flattening
destroys its physical shape and may change its crystalline orientation.
I nfrared Reflection Measurements
In 1 95 9 spectroscopists began exploring reflection techniques for IR
analysis. Francis and Ellison investigated films on mirrored surfaces, but
their technique of external reflectance did not become widespread until
the 1 970s ( Francis and Ellison 1 95 9 ) . The technique of internal reflection
spectroscopy ( IRS), also called attenuated total reflection (ATR), was
introduced in the early 1 9 60s and quickly became popular, since almost
any material-solid, powder, or liquid-could be easily and nondestruc
tively analyzed. Diffuse reflection spectroscopy (DRIFTS) methods pro
duced so little reflected IR radiation that they were not widely used until
the development of FT-IRs.
Figure 4 . 1 2 illustrates the beam reflection paths used by dif
ferent types of IR reflection devices. In external reflectance measure
ments, the angle of reflection is equal to the incident angle of the beam,
as found in mirrorlike reflections. For this method, the IR beam may be
Internal
reflected either by the sample surface ( specular ) or by a mirror surface
reflection
under a thin layer of sample (reflection-absorption) . DRIFTS occurs with
High-refractive-index crystal
a rough, porous, or powder sample, where the light is reflected at numer
ous angles that are not equal to the incident angle. IRS occurs when the
incident beam is internally reflected in a high-refractive-index material
placed in contact with the sample. Leyden and Murthy and Morris pro
Figure 4 . 1 2
Three different reflection types
vide good comparisons of each of these reflection methods ( Leyden and
(n A
Murthy 1 9 8 6 ; Morris 1 99 1 ) .
nB
= refractive index of air;
= ex =
refractive index of the reflecting
material;
angle of incidence).
Each o f these types o f analysis methods can cause slight shifts
in absorption band position, as well as changes in relative band intensi-
61
Infrared Analysis Methods
Analysis method
Correction program
Difference from transmission spectra
I nternal reflection
none
band intensities stronger than normal
at low wave n u m bers, weaker than
normal at high waven u m bers
( I RS)
Diffuse reflection
( D R I FTS)
K u belka- M u n k
some slight band shifting and i ntensi
fication of weak bands
artifiCially flat basel i nes
Table 4 .4
Spectral alterations due to reflection analy
Specular reflection
Kramers-Kronig
shifting i n position of bands,
derivative band shapes
Reflection-absorption
(R-A)
none
may contain interference fringes and
a specular component, if the surface
of the sample is shiny
sis methods, as compared to transmission
spectra.
ties. Table 4.4 provides a summary of some of the changes that are seen
in reflectance spectra as compared to spectra collected by transmission
methods. Also, an expansion of the carbonyl region of the spectra from
Figure 4 . 1 is shown in Figure 4 . 1 3 , to illustrate the changes in peak
shape and position.
'":='"g(I)
Transmission
E
<f)
c
t=
if.
Attenuated total reflection
( ATR)
�a:1i5u(I)
1il
Diffuse reflection
( DRIFTS)
if.
Figure 4 . 1 3
Partial I R spectra showing a n expanded
carbonyl region of Acryloid 8-72 obtained
from four analysis methods. While the
overall spectral pattern is sim ilar for the
four methods, slight differences in band
Specular
reflection
position and intensities warrant caution
when spectra analyzed by different meth
ods are compared. (The full spectra are
shown in Fig. 4 . 1 .)
1 800
1 700
Wavenumber (cm - 1 )
62
Chapter
4
Specular reflection
One type of external reflection, called specular reflection, occurs when the
shiny surface of the sample reflects the IR beam at an angle equal to the
angle of incidence. The specular reflection technique is used on samples
of all sizes. Accessories for either fixed- or variable-angle reflection of the
incident beam are available that fit into the IR bench sample compart
ment. Figure 4 . 1 4 shows a variable-angle external reflection unit. The
angle of incidence is adj usted to obtain optimum beam penetration on a
sample-and thus optimum sensitivity. Usually a high angle of incidence
( 70°-8 9 ° ) is best ( Harrick 1 979). Larger top-loading external reflection
attachments are available for the horizontal placement of samples; they
can accommodate any large, flat surface placed face down.
Specular reflection spectroscopy is a nondestructive technique
in that the analyzed sample does not need to be removed for analysis.
However, for high-quality spectra, the sample should be highly reflective
and thus may require polishing prior to analysis. In a vertical reflection
holder, the sample is generally clamped in place.
The large number of polished paint cross sections already
in existence in museum labs is an ideal resource for specular reflection
microanalysis. Applications presented in Chapter 6 illustrate the combi
nation of specular reflection analysis and computer-controlled stage
movement to perform linear- and area-concentration maps on polished
cross sections. Relative variations in paint layer composition can be
determined by specular reflection, but identification of components in
the samples may require supplemental analysis by other techniques.
In specular reflection, strong absorption bands appear as
derivative-shaped curves because of dispersion of the radiation. The
derivative-shaped bands are referred to as Reststrahlen (residual ray)
bands. This effect is dependent on the wavelength, angle of incidence,
intensity of absorption, and refractive index of the sample material.
Specular reflectance spectra can be converted to transmittance-like spec-
Figure 4 . 1 4
A variable-angle external reflection acces
sory. The sample is placed horizontally on
the holder over the angled m i rror. An
additional sample holder (shown at left) is
available to orient the sample in a vertical
positio n .
I nfrared Analysis Methods
63
tra with a Kramers-Kronig transformation, which calculates refractive
and absorption indices from the specular data . Most IR data processing
programs can perform Kramers-Kronig transformations. Such a transfor
mation works well when the spectrum results only from specular reflec
tion; however, other types of reflections, refractions, and scattering can
occur, such that bands of different shape and position are produced. For
further information on specular reflection, refer to Kortum ( 1 96 9 ) .
Reflection-absorption
A second type of external reflection, called reflection-absorption ( R-A),
occurs when the IR beam passes through a thin film of sample and is
reflected from a nonabsorbing substrate. When the incident radiation
enters the film at a near-normal angle ( 9 0 ° ) , the method is essentially
a double-pass transmission experiment. Spectra generated in this man
ner resemble those obtained in transmission . Reflection-absorption
experiments can also be conducted at a greater angle of incidence
( 6 5°-8 5 ° ) , thereby increasing the effective pathlength of the sample.
This is called grazing-angle spectroscopy and is used to detect and
analyze very thin films.
Front-surface aluminum or gold mirrors are used as reflective
surfaces for thin films in a reflection-absorption experiment. The sample
liquid, polymer, particle, or fiber-is smeared, melted, or flattened onto
the mirror to form a thin, smooth, and level film. The mirror with sample
is then placed in a specular reflection apparatus or on a microspectrom
eter stage for reflection analysis.
Specular reflection is the most common spectral distortion in
a reflection-absorption experiment. It occurs when the sample is shiny
and some of the radiation is reflected from the surface of the sample
rather than from the mirror. To eliminate the specular component, the
sample surface may be abraded, or a nonabsorbing material (e.g., salt
plate) may be placed on the surface of the sample ( Reffner and Martoglio
1 99 5 ) . A salt plate must be held tightly against the sample surface to pre
vent interference fringes from occurring. A compression cell can be used
for this purpose .
Diffuse reflection
For a non-mirrorlike surface, light is reflected diffusely, or in all direc
tions. When all specular contributions are eliminated, DRIFTS can be
related to the concentration in the sample by use of the Kubelka-Munk
equation ( Kubelka 1 94 8 ) . This conversion makes the spectra analogous
to absorbance plots for transmission spectra.
DRIFTS has been used in the visible region for many years
for the quantitative analysis of colorants ( Billmeyer and Saltzman 1 96 6 ) .
For IR analysis, DRIFTS was tried as early a s 1 9 1 3 b y Coblentz, and it
was later used for the examination of powdered samples ( Clark 1 964;
White 1 964; Vincent and Hunt 1 96 8 ) . It gained popularity in the late
1 970s when an efficient collector designed for diffuse radiation was used
in combination with the high-energy throughput of an FT-IR ( Fuller and
Griffiths 1 978a, 1 9 78b, 1 9 8 0; Griffiths and Fuller 1 9 8 2 ) .
64
Chapter
4
In the field of art conservation, Meilunas used DRIFTS to
examine the surface of paint films and inks ( Meilunas 1 9 8 6 ) . He found
that while many pigments could be identified, specular reflection inhib
ited the identification of binders. Shearer used silicon carbide paper both
as a sampling tool and as a DRIFTS substrate for the analysis of archae
ological organic residues ( Shearer 1 9 8 7) . Using DRIFTS as a nondestruc
tive tool, Hedley and coworkers ( 1 990) analyzed surfaces of paintings
before and after solvent cleanings; Perron ( 1 9 8 9 ) characterized emulsions
on photographs; Poslusny and Daugherty ( 1 9 8 8 ) identified the adhesives
on stamps; and Faraone ( 1 9 8 7 ) examined the weathering surfaces of
stones. McGovern and Michel used DRIFTS in combination with other
techniques to determine the composition of royal purple dye, while
Dauphin applied it to the quantitative analysis of protein residues found
in archaeological bones (McGovern and Michel 1 990; Dauphin 1 99 3 ) .
DRIFTS attachments are designed to fi t i n the standard sample
compartments of most spectrometers ( Fig. 4 . 1 5 ) . The light reflected from
the sample is collimated by an ellipsoidal mirror, then directed to the
detector. The sample is held in a small cup on a sliding metal strip that
serves to position the sample reproducibly. Some commercial DRIFTS
accessories are designed to block the collection of the beam reflected at
the angle equal to the incident angle-that is, the specular reflection com
ponent. This feature eliminates one problem source in DRIFTS.
Powder samples are prepared in a manner similar to that for
Figure 4 . 1 5
KBr pellets. First, the sample is finely ground and mixed with KBr ( or
A DRI FTS u n it with normal and m icro
KCl) powder. Since the resolution of the spectrum is dependent on the
(custom- machined) sample cups. Samples
particle size, it is critical to grind the sample as finely as possible.
are held i n a four-position holder that
Distorted absorption bands will appear if particle sizes are larger than
slides into position for analysis.
the wavelength of radiation. The mixed sample matrix is then scooped
into a sample cup and packed gently with a tamper. The prepared sample
must be level and uniformly packed to produce a good-quality spectrum.
The IR beam penetrates only the top 0. 5-2 mm of the sample. Thus, for
small samples, it is possible to fill the bottom half of the cup with pure
KBr powder, then put the sample matrix in the top half of the cup, to
produce a more concentrated sample. Also, microsamples may be ana
lyzed in microcup sample holders that are smaller in diameter and shal
lower than the regular cups.
Solutions may be analyzed by dripping a few microdrops on a
prefilled analysis cup of KBr and allowing the solvent to evaporate. If the
drops disrupt the surface of the salt bed, it may be possible to smooth
the dried surface by gently tamping it, either directly or by first adding a
few sprinkles of KBr powder on top.
For nondestructive analysis of solid samples, any matte sur
face, such as dyed textiles or papers, may be placed at the focal point of
the IR beam in the DRIFTS apparatus (Harrick Scientific Corp . 1 9 8 7 ) .
Shiny o r smooth surfaces may need t o be roughened with emery paper to
diffusely reflect the incident beam. Also, a sample may be collected from
a solid by gentle abrasion with a small circle of silicon carbide paper; the
sample on the silicon carbide substrate is then mounted on a holder and
placed in a DRIFTS accessory for analysis ( Shearer 1 9 87; Pretzel 1 99 4 ) .
I nfrared Analysis Methods
65
In this manner, small amounts of sample can be taken from surfaces with
minimal damage. The thin layer of sample on the reflective silicon car
bide substrate essentially produces a reflection-absorption experiment
with a spectrum similar to that obtained in transmission. The spectrum
should not need the Kubelka-Munk correction used for other diffuse
reflectance spectra.
Typically, all DRIFTS samples should be diluted to less than
30 w/w% concentration in a nonabsorbing matrix. On solid samples, this
dilution can be done by sprinkling a thin layer of nonabsorbing material
(e.g., KBr) over the surface of the sample. The powder layer minimizes
band broadening and poor resolution effects resulting from saturation or
specular reflection problems; additionally, the sensitivity of the measure
ment is improved by an increase in the depth of penetration of the beam.
Spots on thin-layer chromatography plates may be successfully analyzed
in this manner ( Zuber et al. 1 9 8 4 ) .
The diffuse reflectance spectrum depends on sample density
and refractive index, as well as on particle size and morphology. For
quantitative analysis, the Kubelka-Munk function is used to relate the
absorption coefficients to the material's concentration. This function
tends to enhance the strong absorption bands and decrease the weaker
bands in comparison to transmission spectra. Additionally, the baseline
may be artificially flattened. For nonquantitative work, the diffuse
reflectance spectra may be displayed without any correction function.
The maj or problem that can occur with diffuse reflectance spectra is the
inclusion of a strong specular reflection component that produces slight
band distortions.
Internal reflection
Internal reflection was first noted in 1 7 1 7 by Isaac Newton in his studies
of total reflection at the interface of two different media. The phenome
non is observed in a clear glass of water, where one sees total reflection by
viewing the water's surface from slightly below the water level (Harrick
1 9 79 ) . Total reflection is destroyed when another material, such as a
finger, is placed in optical (air-free ) , or intimate, contact with the glass. In
optical contact, the ridges on the finger surface can be clearly seen-but
not the valleys, where no contact is made. In 1 947 Goos and Hanchen
described the interactions between light and the two materials as total
internal reflection, and the interactions were subsequently used for record
ing optical spectra ( Goos and Hanchen 1 947). Internal reflection was
applied to IR spectroscopy by Harrick ( 1 959) and Fahrenfort ( 1 962).
While Fahrenfort coined the name attenuated total reflection (ATR) , the
American Society for Testing Materials has since limited the scope of the
term ATR and has instead designated the overall technique as internal
reflection spectroscopy ( IRS) (ASTM 1 9 8 1 ) .
IRS works well with coatings, adhesives, fibers, foams, fab
rics, plastics, and films, and it is the technique of choice for many
opaque and intractable samples. Internal reflectance spectra of films do
not exhibit any of the interference fringes that can occur in transmission
spectra. In a development significant to the field of art conservation,
66
Chapter
4
Paralusz did an extensive study using IRS of adhesive tapes ( Paralusz
1 974 ) . This paper included studies on resin aging, delamination, and
resin-plasticizer migration. An interesting paper by Wilks showed varied
applications of ATR, from the analysis of skin to gas chromatography
fractions (Wilks 1 96 7 ) . In 1 9 8 5 Cain and Kalasinsky used several analyt
ical methods to examine the degradation products on nineteenth-century
paper ( Cain and Kalasinsky 1 9 8 5 ) . They found that IRS was useful for
the determination of gelatin size in the paper samples. More recently, IRS
has been used as a nondestructive method to examine eighth-century
Japanese fabrics ( Matsuda and Miyoshi 1 9 8 9 ) and to identify synthetic
fabrics ( Cardamone 1 9 8 8 ) .
In IRS, the incoming radiation enters a high-refractive-index
From source
material ( hence called an IRS element) and is internally reflected, usually
multiple times ( Fig. 4 . 1 6 ) . Based on the fact that internally reflected IR
radiation will penetrate a short distance into a lower-refractive-index
medium, a sample in optical contact with the surface of the IRS element
To detector
Figure 4 . 1 6
Multiple internal reflections i n a n I RS ele
ment. When the I RS element has a higher
refractive index than the sample, the IR
rad iation will penetrate slightly into a
sample if it is in optical contact with the
element.
will be exposed to IR radiation. The sample can then absorb the radia
tion and produce a spectrum. Only the surface of the sample is analyzed,
since the beam penetrates j ust a few micrometers into the sample. The
depth of penetration is proportional to wavelength, and therefore, an
increasing depth of penetration is observed at higher wavelengths ( lower
wavenumbers ) . The intensity of absorbed radiation is dependent on the
amount of sample in contact with the surface of the IRS element and the
number of contact points that the radiation has with the sample-element
interface. Thus, increasing the number of reflections increases the inten
sity of the IR absorptions. Varying the angle of incidence can change the
number of reflections and their position within the IRS element.
For IRS to occur, the IRS element must have a refractive index
higher than the sample to be analyzed ( see Table 4.3 for refractive index
values). The IRS element material must also be clean, have a high surface
polish, and be transparent to IR radiation. Silicon, germanium, thallium
bromoiodide ( KRS-5 ), AgCI, and zinc selenide ( ZnSe) are typically used
as IRS elements. Germanium and silicon are hard and brittle. They do
not scratch easily; they are, however, subject to breaking. They may be
cleaned in water, solvents, and dilute acids. KRS-5 elements, the most
commonly used, tend to be soft and can retain the imprint of nonflat
samples that are pressed into them. They can be cleaned with hydro
carbon solvents, acetone, or alcohol. AgCl, while softer and more flexible
than KRS-5, is light sensitive and inexpensive enough to be discarded
when damaged. ZnSe is expensive and brittle but hard and insoluble.
It is important not to scratch the optical surfaces of the IRS
elements, and all handling should be minimized. Many samples, includ
ing powders, may be removed from the elements with pressure-sensitive
adhesive tape. Thin films and residues may be cleaned with a wash bottle
or, if necessary, an ultrasonic bath. Rubbing of the surfaces of IRS ele
ments should be avoided. Polishing can often refurbish damaged or
scratched IRS elements, but because of their toxic nature, it is often
best to return the IRS elements to the manufacturer for reconditioning.
Pressure plates should be wrapped in an uncoated variety of aluminum
Infrared Analysis Methods
67
foil th �t may be discarded after each analysis to prevent cross contamina
tion between samples.
Sample preparation for IRS analysis is relatively simple. The
sample is placed on an IRS element (preferably on both sides ) , then the
IRS element is positioned in its holder between two pressure plates that
are uniformly compressed to place the sample in contact with the IRS ele
ment (Fig. 4 . 1 7) . As the pressure is raised, the amount of sample in optical
contact with the IRS element is increased, thereby enhancing the absorp
tion intensity. For quantitative or comparative work, a torque wrench is
recommended to reproducibly tighten the holder for each sample.
Samples, such as films, may need to be cut so that they do
not exceed the length of the optical element and interfere with the beam
path. Long fibers may be wound around the IRS element to produce an
even sample surface. Fibers may also be placed on the bias to prevent
orientation effects. To do this, small strips of the fiber are cut, then
placed diagonally, adj acent to one another and completely covering a
strip of tacky adhesive. The tape is then placed in a manner such that
only the fibers, not the adhesive, touch the IRS element. Powders may be
evenly spread on an IRS element, or they may be dispersed in a liquid for
deposition on the IRS element. For hard samples, the pressure plates can
be lined with a thin foam or thick adhesive and then covered with
uncoated aluminum foil. This procedure will minimize deformation to
the IRS element's surface. Liquids, gels, pastes, and even aqueous solu
tions can be cast onto an IRS element or run in a cylindrical internal
reflection cell ( CIRCLE; see Suppliers, Spectra-Tech, Inc . ) . A long ATR
probe, originally developed by Wilks Scientific, can be immersed in liq
uids and solids for analysis outside of the instrument sample compart
ment ( needle probe; see Suppliers, Spectra-Tech, Inc . ) .
The IRS element holder typically fits into a beam condenser
unit in the sample compartment. For optimum performance, it is critical
that the beam condenser be aligned to provide maximum IR beam inten
sity at the detector. The beam condenser should be aligned initially with
out a sample, after which point a background scan can be obtained. The
alignment should be rechecked with every single sample that is analyzed,
because the position of the element can vary with the thickness and posi
tion of the sample, as well as with the placement of the IRS element.
Figure 4 . 1 7
An IRS holder, elements, a n d torq ue
wrench. The sample is placed adjacent to
an I RS element, then positioned between
the two pressure plates (covered in alu
minum foil) of the holder. A torq ue
wrench is used for even tightening of the
screws that hold the pressure plates
around the sample.
68
Chapter
4
Otherwise, the energy losses due to poor alignment will cause significant
deterioration of spectral quality.
The instrument usually contains a white light source for the
rough alignment. Turning out the room lights will aid in the process.
When the IRS element is properly positioned in the beam, it will glow. In
fact, in a dark room, it is possible to see the points of contact of the
beam with the sample-element interface. This feature is useful for the
analysis of small bits of sample. These points can be marked on the top
surface of the pressure plate; the holder can be removed from the instru
ment and disassembled; and the sample bits or fibers can be positioned in
these places for optimum beam contact. Theoretically, there should be no
" dead spots" for angles of incidence
:s
4 5 ° . In practice, however, there do
seem to be regions that are more sensitive than others.
In IRS, the quality of the spectrum depends upon the angle of
incidence, the depth of penetration, the number of reflections, and the rel
ative refractive index difference between the sample and the IRS element.
The spectra of thin films are virtually identical to spectra collected by
transmission methods. For thicker samples, however, absorption bands at
smaller wavenumbers are more intense, since the depth of penetration
into the sample increases with wavelength. Poor spectra are obtained
when the sample is not in intimate contact with the IRS element.
Infrared Microspectroscopy
The coupling of a microscope to the IR spectrophotometer produces a
system capable of doing IR microspectroscopy. The resulting apparatus,
called an IR microspectrophotometer, was first made commercially in
the 1 950s ( Cole and Jones 1 95 2 ) . Although the design of the microspec
trophotometer was satisfactory even by today's standards, the system
proved to be costly and was limited by the low energy throughput and
corresponding low signal-to-noise ratios. Therefore, the introduction of
the FT-IR, with its inherent advantages, as well as advances in IR detec
tor technology, fueled the reemergence, in 1 9 8 3 , of the IR micro spec
trophotometer. The recent success in application of this instrumentation
to many areas of research ( semiconductors, polymers, and pharmaceuti
cals ) , as well as forensic investigation, has established the technique of
IR micro spectroscopy as a powerful tool in the analysis of small samples.
For more information on the history, design, and operation of IR
microspectrophotometers, see Roush 1 9 8 7; Messerschmidt and
Harthcock 1 9 8 8 ; Katon, Sommers, and Lang 1 9 8 9-90; Katon and
Sommers 1 9 92; Reffner 1 9 93; and Humecki 1 995b.
Researchers quickly saw the applications of IR microspec
troscopy to the analysis of tiny samples from works of art. The first
published application of IR micro spectroscopy was for the analysis of
painting materials, done with a dispersive spectrometer by van't Hul
Ehrnreich ( 1 970). Later, the attachment of microscopes to FT-IRs stimu
lated numerous applications for the analysis of paint layers, binding
media, varnishes, waxes, dyes, and other materials ( Shearer et al. 1 9 8 3 ;
I nfrared Analysis Methods
69
Baker et al. 1 9 8 8 ; van Zelst, von Endt, and Baker 1 9 8 8 ; Orna et al.
1 9 8 9 ; Jakes, Katon, and Martoglio 1 9 90; Martoglio et al. 1 990; Derrick,
Landry, and Stulik 1 9 9 1 ; Tsang and Cunningham 1 9 9 1 ; Derrick et al.
1 9 92; Lang et al. 1 992; Derrick 1 9 9 5 ) .
Microspectrophotometer design
The first IR microscopes were positioned in the sample compartment of
the IR spectrophotometer. The microscope contained all the necessary
transfer optics to direct the IR beam from the spectrometer source to the
sample positioned on the stage of the microscope. In a transmission exper
iment, after it passed through the sample, the IR radiation was collected
and directed back into the spectrophotometer and onto the detector. The
optics used in IR microspectrophotometers are reflecting optics. Since both
glass and quartz absorb IR light over much of the region of interest, the
IR microspectrophotometers are unable to employ standard, visible-light
refracting (lens) optics but rather must use reflecting (mirror) optics.
Although other detectors were used, the detector of choice
was, and continues to be, the mercury-cadmium-telluride ( MCT) detec
tor. The MCT detector element is cryogenically cooled to liquid nitrogen
temperature, thus providing high sensitivity and signal-to-noise values
necessary for the low energy levels and small sampling areas found in
IR microspectroscopy. As the microscope designs gradually changed, a
major improvement in signal-to-noise levels was achieved when the
MCT detector was repositioned from the spectrophotometer bench to the
microscope apparatus, in order to minimize the IR beam path after inter
action with the sample.
The next wave of improvements came when IR spectropho
tometers were built with the ability to direct the IR source beam external
to the instrument. This flexibility allowed modifications, redesign, and
production of new spectrometers with optimal geometry for coupling to
IR microscopes. Since the IR microscope had its own onboard detector, it
was a complete system, minus the IR source and data processing/com
puter system. With this new design, the microscope no longer occupied
the sample compartment of the spectrophotometer, so that conventional
methods could still be used to analyze macro samples.
Finally, another design has produced what may be considered
the first true IR micro spectrophotometer. In this system, the IR spec
trophotometer and microscope are no longer separate entities but are,
instead, one unified body ( IRf.LS; see Suppliers, Spectra-Tech, Inc .; Fig.
4 . 1 8 ) . This apparatus is not capable of macrosampling but, rather, has
been designed to maximize the information and sensitivity obtainable on
microscale samples. Samples can be examined with polarized light and
digital imaging techniques, in addition to IR microspectroscopy.
Microspectrophotometer capabilities
All IR microspectrophotometers have some type of visible-light imaging
available. Indeed, this aspect is one of three that separates the IR micro
spectrophotometer from the IR beam condenser accessory. Imaging capa
bilities range from stereomicroscope viewing to that of a research-grade
70
Chapter
4
Figure 4 . 1 8
An I Rf.LS I R microspectrophotometer
(Spectra-Tech , I n c . ) . The instrumentation
contains a source, interferometer,
computer-controlled sample stage, and
detector i n one u n ified body, shown on
the left. Also shown are a video camera,
monitor, and data processing computer.
optical microscope. In addition, most IR micro spectrometers provide
photomicroscopy and/or videomicroscopy.
A second characteristic of the IR micro spectrometer is the
ability to isolate a particular area of the sample optically by the use
of movable apertures. Apertures may be a fixed-diameter-circle or a
variable-circle iris, or an adj ustable, knife-edge rectangle. For hetero
geneous samples, this capability means the IR microspectrometer is able
to achieve both sample isolation and component identification.
Finally, all IR microspectrophotometers have the ability to
collect IR reflectance spectra. Reflection IR is useful for highly absorbing
samples that do not transmit IR well, as well as for providing informa
tion on the surface composition of a material. The resulting spectrum is
often a complex mixture of specular and diffuse reflection components
and must be interpreted with care. The ability to perform reflection
analysis increases the versatility of the IR microspectrophotometer.
Particle and fiber analysis
Many of the techniques previously described in this chapter can be
applied to IR microspectroscopy, and, as with macroanalysis, the selec
tion of the technique depends on the characteristics of the analyte. Most
materials are heterogeneous; however, to facilitate examination of typical
analytical variables, this discussion will be limited to simple samples with
homogeneous analysis areas.
The most common analyses performed by the IR micro spec
trophotometer involve the determination of particle and fiber composi
tion. In the field of IR microspectroscopy, a particle is simply defined as a
piece of material of suitable size for IR micro spectroscopic analysis. The
size suitable for analysis includes pieces as small as 1 0 !Lm in diameter,
up to sizes on the order of 1-2 mm.
The initial examination and manipulation of a particle is
done under a stereomicroscope, usually with the sample on a glass
microscope slide. A necessary component of any IR microspectroscopic
I nfrared Analysis Methods
71
x 1 0- x S O
laboratory, the stereomicroscope should have variable-magnification
capability, such as
magnification. A stereomicroscope with the
head mounted to a boom arm is a valuable tool that provides flexibility
for a wide variety of samples.
For transmission analysis, the first step is to place the par
ticle on the IR window material, such as a salt plate or a diamond cell
( Fig. 4 . 1 9 ) . Corresponding procedures can also be used for reflection
absorption measurements if the particle is placed on a polished metal
plate. The most important tools for particle manipulation are the probe
Figure 4 . 1 9
Typical I R alkali halide pellets in I R
microspectrometer holders a n d a com pres
sion cel l .
and the forceps. Each of these tools is available in a variety of shapes
and sizes from a host of suppliers. The selection of the appropriate probe
or forceps is a matter of taste. Some IR microspectroscopists suggest very
fine tools for the manipulation of small particles. However, if the probe
is too fine, it can damage the particle. A particle can be transferred by
touching it with the probe while observing it under the stereomicroscope.
The probe is lifted slightly, and with the free hand, the IR window is
brought into view under the stereomicroscope. The probe is lowered
until it touches the surface of the window, then gently turned to release
the particle. If the probe and particle are kept under the microscope,
there is less chance that a valuable sample will be lost. Once the sample
is on the analysis window, it is usually flattened with a probe, roller, or
another window (e.g., a diamond cell ) .
For efficiency, multiple samples can b e prepared o n one salt
plate for IR transmission analysis. To prevent confusion, detailed draw
ings of each sample's position and shape should be made before the pellet
is transferred to the IR microspectrophotometer. A label can be scratched
into the salt pellet next to each sample. One good method is to prepare
the samples as if they were on a clock face. Another system was devel
oped by Hill; in this method, a numbered grid is scratched into the pellet
( Fig. 4.20), and a sample is placed within a square (Hill 1 99 3 ) . With this
procedure, the samples' positions can be easily recorded in the notebook;
the position numbers are readily discernible under the IR microspectro
photometer, and chaos is not introduced if the pellet is rotated when
transferred to the analysis stage.
Once prepared, the IR window with sample is placed on the
analysis stage of the IR micro spectrophotometer. Although the details of
instrument adj ustments and alignments vary depending on the manufac
turer, certain operations are carried out in all IR microspectroscopic
analyses. First, using the visible-light capability of the microscope, the
Figure 4.20
A photom icrograph
( x 20)
of a labeled grid
particle is brought into focus and centered in the field of view. After this,
scratched into an NaCI pellet. This method
the condenser should be checked to ensure that it is at the correct focal
helps locate multiple samples placed on
point for that particular sample and its substrate material. These focus
one window.
ing and centering steps are critical for accurate spectral results.
Apertures are used to isolate the particle, as shown in Figure
4 .2 1 . Rectangular, knife-edge apertures are the most common. When pos
sible, the edges of the samples should not be included in the analysis
area, since the curved edge of the sample can act as a lens and cause dif
fraction of the beam; this effect is significant in single-aperture micro
scopes (Messerschmidt 1 9 8 8 ) . Once isolated, the sample stage is moved
72
Chapter
4
Flattened particle
Fiber
Cross section
Figure 4.21
Rectangular aperture selection for a homo
geneous particle, a fiber, and a cross sec
tion layer. Each of four knife-edge
apertures is positioned to block the I R
radiation from regions not selected for
analysis.
to expose a portion of the IR window where no sample is present. A
background single-beam spectrum is collected ( Fig. 4.22). The stage is
then moved back until the sample is brought back into view. The sample
is scanned and ratioed to the background spectrum, and a transmittance
( % T) versus cm- 1 IR spectrum is produced. The isolation and analysis
steps may be repeated for the analysis of various particles loaded on a
single IR window. If the size of the aperture is changed from one particle
to another, or if the particles are located far away from one another on
the window, it is advisable to collect a new background single-beam
spectrum before scanning the next particle.
Fiber analysis is handled in much the same manner. The
transfer of the fiber to the window can be achieved with either the probe
or forceps. Knife-edge apertures can also be used to isolate the fiber, as
shown in Figure 4 .2 1 . Since many fibers are less than 40 /-Lm in width,
the aperture is usually elongated along the axis of the fiber. This elonga
tion yields a greater sampling area, which in turn produces a better
signal-to-noise ratio in the measurement.
As the size of the aperture in the sample stage ( x-y) plane
increases, the higher energy throughput for analysis of the sample is
73
I nfrared Analysis Methods
Background
Q)t'()'"'"
�if!.
.�if!.�()'"cE
c
E
(f)
c
4000
3600
600
3200
Polystyrene
Q)
Ul
c
4000
3600
3200
Ratioed polystyrene spectrum
Figure 4.22
A single-beam background spectru m , a
single-beam polystyrene spectru m , and the
resultant ratioed polystyrene spectru m .
4000
3600
3200
2800
2400
2000
1 800
1 600
1 400
1 200
1 000
800
600
Wavenumber (cm- 1 )
reflected in the magnitude of the signal seen at the detector. Figure 4.23
illustrates this effect. The top spectrum is the result of measuring a
20 f.1m width of a sample 1 00 f.1m in length. Below is the spectrum
for the same sample analyzed with a larger aperture measuring
100 x 1 00 �m. A larger aperture area yields a spectrum with less
nOise for the same resolution and sampling time.
Diffraction effects become particularly important when aper
tures are employed. If light is passed through a small slit, the light rays
may bend, as shown in Figure 4.24. This process is referred to as diffrac
tion. The top drawing shows the diffraction effect for the case in which
the slit size, x-y, is much greater than the wavelength of the radiation,
A.
Chapter
74
4
OJ
U
C
:e.=<ft.'"'"
E
<fl
C
4000
3600
3200
2800
2400
4000
3600
3200
2800
2400
2000
1 800
1 600
1 400
1 200
1 000
2000
1 800
1 600
1 400
1 200
1 000
Figure 4.23
Two spectra showing the effects of a vary
ing aperture area for the same sample,
x
x
wh ich is greater than 1 00
1 00 !-1m. The
top spectrum was collected with an aper
ture of 2 0
1 00 !-1 m . The bottom spec
trum was collected with an aperture of
1 00 x 1 00 fLm . Note the difference i n
noise . I t is best t o use t h e largest apertu re
that the sample and instrument will allow.
800
600
Wavenumber (cm- 1 )
Note that the diffraction is small. But as the slit size approaches the
wavelength of the radiation, as in the bottom drawing, the diffraction
becomes more pronounced. Thus, diffraction is a limiting factor that
relates to the minimum aperture size used in the IR micro spectroscopic
experiment. The longest wavelengths of IR light used in the typical mid
IR experiment are on the order of 10 ,..,.,m . Therefore, this figure repre
sents the resolution limit achievable in IR microspectroscopy. Apertures
smaller than this will yield sample information from outside the region
of interest, even though such areas are not visible through the aperture.
Recent experiments at the Getty Conservation Institute found that a bet
ter rule of thumb is to employ apertures no smaller than 20 ,..,.,m in width.
This guideline ensures good quality in the resulting IR spectrum.
It is important to differentiate between the width of a sample,
as described above, and its thickness. The thickness of the sample (z
direction) is one factor that determines the absorbance of the material.
Figure 4.25 shows two spectra of the same sample at two different thick
nesses but measured with the same parameters. The top spectrum is for
the sample when it is too thick. Because some bands are totally absorb
ing, the usefulness of the IR spectrum is reduced, and it is a poor can
didate for any mathematical routine, such as spectral searching or
75
I nfrared Analysis Methods
I�"''' "' --,
"
subtraction. The bottom spectrum was collected after the sample was
thinned. This time, all absorption bands are on scale. A good rule of
thumb is that the % T for the most intense band should not be less than
1 0 % T ( or greater than 1 . 0 absorbance units ) . Appropriate sample thick
�-
nesses for use in IR analysis range from 1 f1m to 20 f1m, depending on
the molar absorptivity of the compound of interest .
..
In terms of particle and fiber analysis, flattening of the
sample may be required to obtain the desired sample thickness. Several
options are available. First, the sample can be flattened with a metal
y
..I -..L. .J .J J
probe or roller blade. Flattening can be done on a glass or metal surface
prior to placement of the sample on the window; however, this procedure
can make the sample fragile and difficult to transfer. The sample can also
be flattened directly on the window or diamond cell. The advantage of
pressing the sample directly on the window is that the sample is more
likely to lay flat on the surface. For a good spectrum, it is important that
the sample be flat and in focus; there should also be no air between the
sample and its substrate.
A second method of flattening the sample is to place another
transparent window on top. Commercially available compression cells
Figure 4.24
The effects of aperture slit size on diffrac
tion. The top illustration shows that dif
fraction is minor when the aperture slit
(x-y) is wide. The lower ill ustration shows
()
OJ
c
co
i:'
E
'"
c
co
F
if.
that when the aperture slit (x-y) is narrow,
near the wavelength of radiation
(A),
dif
fraction is sign ificant.
4000
3600
3200
2800
2400
2000
1 400
1 200
1 000
800
600
4000
3600
3200
2800
2400
2000 1 800 1 600 1 400
Wavenumber (cm- 1 )
1 200
1 000
800
600
1 800
1 600
()
OJ
Figure 4.25
Two spectra showi ng the effects of sample
thickness. The top spectrum is of a sample
c
co
i:'
E
'"
c
co
F
if.
of glue that is too thick; some absorption
bands are totally absorbi ng. The bottom
spectrum was collected from a thinner
area of the same sample; all absorption
bands are on scale.
76
Chapter
4
with alkali halide plates or diamond windows can be used to carry out
this operation with good results. A nice by-product of compressing the
sample is the corresponding increase in sample area. Placing a window
on top of the sample is also an important step if the sample-such as a
fiber-is not flat; a curved upper surface will bend the light and decrease
the energy transmitted to the detector. When two IR windows are used,
however, the increase in total thickness will also decrease the energy
reaching the detector and may change the low-wavenumber cutoff point
for the experiment. If this is a problem, two 1 mm windows, instead of
the normal 2 mm windows, may be used. Alternatively, once compressed,
a sample, unless it is elastomeric, will normally remain flat. Therefore,
the upper compression window can be removed from the cell and the
analysis done with the sample on a single window.
In either the compression cell or the diamond cell, a back
ground spectrum is collected in an area adj acent to the sample, with the
beam passing through the upper and lower windows. Because of the
thickness of the sample, these windows typically have a small air space
between them that can produce interference fringes in the background
(Sommer and Katon 1 9 8 8 ; Reffner and Martoglio 1 9 95; see also Fig.
4 . 1 0 ) . To eliminate these fringes, a small cube of salt (NaCI, KBr, BaF2,
etc . ) is placed next to the sample prior to compression. The background
spectrum is then collected through the pressed-salt region, and the air
gap and its ensuing fringes are eliminated.
For heterogeneous particles and fibers, visually different
regions of the sample can be isolated and analyzed. This approach pro
vides a convenient separation technique without the need for additional
sample preparation steps requiring time and energy.
Cross section analysis
Many samples encountered in art conservation are composed of multiple
layers. The obvious example is a paint chip from a painting. One
approach to handling this type of sample involves manual separation of
the layers for analysis. The sample is placed under the stereomicroscope.
After some observation and identification of the structure, the analyst
picks off representative particles from each of the layers. The particles
removed are then analyzed as described above . This technique works
well with samples that have easily identifiable layers. The major draw
backs to this technique include the time and care needed to perform the
separation. In addition, removal of a single particle, particularly from
hard samples, may be difficult.
An alternative approach is to embed the sample in an appro
priate medium and then to microtome it into thin cross sections. Once
the mold, containing sample and medium, has hardened, it can be
mounted in a microtome and sliced into thin sections for sequential
analysis of layers under the IR microspectrophotometer.
The analysis of the thin cross section is very similar to that of
particles and fibers, in that apertures are used to isolate the area of inter
est. In the case of a multilayer sample, the apertures are used to isolate
a single layer within the sample. This procedure is illustrated in Figure
77
I nfrared Analysis Methods
4 .2 1 . After the IR spectrum for one layer is collected, another layer can
be isolated and its spectrum collected. In this way, the composition of
each layer can be determined.
Mapping studies
Molecular mapping, also known as functional group imaging, involves
t«OJ'sQ.
•6 •7 •9 1•0
the systematic study of the structure of a material of interest; molecular
mapping can be done in either transmission or reflection microspec
troscopy ( Harthcock and Atkin 1 9 8 8 ; Reffner 1 9 89; Krishnan, Powell,
and Hill 1 99 5 ) . Molecular mapping with an IR micro spectrophotometer
is a technique complementary to elemental mapping as achieved in a
scanning electron microscope, and it may often be performed on the
same sample.
Band
In its simplest form, linear mapping is conducted as follows:
1
( 1 ) An aperture of an appropriate size is made, and a background spec
trum is collected in a nonsample area. (2) With the sample stage, the
edge of the cross section is brought into view through the aperture, and
the spectrum is collected. ( 3 ) The sample stage is then moved in one
direction by a given amount to reveal an adj acent area through the aper
ture; once again, the spectrum is obtained. (4) The process is repeated
until the entire cross section has been analyzed. This procedure, known
2
6
Position number
4
8
as IR linear mapping microspectroscopy, is illustrated in Figure 4.26. On
many instruments, this routine can be automated by the use of a map
Figure 4.26
ping stage that is operated either by a controller box or by software from
The I R l i near mapping tech n i q ue . The
the spectrometer computer. Commercially available mapping stage acces
top i l l ustration shows a set of spectral
sories fit many IR microspectrometers. Commercial software is available
collection positions selected for the li near
to help display the information obtained from such an experiment (see
mapping of a m u ltilayer material. The
Suppliers, Galactic Industries Corp.; Spectra-Tech, Inc.; Bio-Rad Digila b ) .
resolution of the map is affected by the
A n area mapping experiment i s done t o yield information
density of the collection sites and the size
about an area of interest; it may be done as a transmitted light experi
of the aperture. For this example, ten
ment on thin sections or as a reflected light experiment on embedded,
spectra were collected. After the spectra
polished paint cross sections. In either case the sample is placed on the
x =
are examined, a few specific absorption
sample stage of the IR microspectrophotometer, and an analysis grid
bands are selected, and their intensity is
containing several hundred points (e.g., 20
30 grid
600 points) is
plotted versus their collection position on
selected for the area of interest on the sample. An array of spectra is pro
the sample to produce a line map, such
duced by the collection of a single spectrum as the aperture moves to
as the bottom figure. Of the absorption
each point on the grid ( Figs . 4.27, 4 . 2 8 ) . The effective resolution of the
bands plotted , only band 2 has an
components in the sample is determined by the size of the analysis aper
in creased intensity from a component
ture and the density of the grid. The size of the aperture for the spectra
in the first layer. Both absorption bands
in Figure 4 . 2 8 was 40 x 20 11m (x-, y-axes, respectively) . The selection of
1 and 2 appear in the spectrum for the
appropriate step size and aperture size involves a trade-off between reso
second sample layer, while none of the
lution, energy throughput, and the length of the experiment. In this case,
plotted absorption bands occur in the
a step size of approximately 20 11m gives an overlap of the windows in
spectrum for layer 3. The last and fourth
the x direction. Overlapping apertures, while not necessary for complete
layer contains absorption bands 2 and 3
sample imaging, do provide an effective increase in the resolution of the
in its spectru m .
components. The collection and processing of the 50 scan spectrum at
each grid point requires about 1 minute. Therefore, a mapping experi
ment with 1 5 0 grid points, such as shown in Figure 4.27, would require
about 2.5 hours.
78
Figure 4.27
4• • •
Chapter
•••••
An example of grid selection for an IR area
map. The dots designate x-y stage loca
tions for the center of an analysis aperture
co
Analysis
apert ure
(example on right) . The resolution of the
components i n the sample is directly
related to the size of the aperture window
and to the density of the grid.
5
4
3
2
Q)
.0<{()ccoo(/)
160.0
140.0 i?
120.0
100.0
80.0 ":JQ
<;:-<oU,s§v r/;
Figure 4.28
A series of spectra collected by computer
from an area grid, such as shown in Figure
4.27. The computer stores the collection
position of each spectrum to use later for
contour plots.
3500
3000
2500
2000
Wavenumber (cm- 1 )
1500
1000
From the array of spectra, contour maps may be produced
that provide information on the concentration and location of com
pounds related to various functional groups in the sample ( Fig. 4.29 ) .
This i s done b y selecting a n absorption band o f interest, such a s a
hydrocarbon band, and plotting its intensity versus its position in the
grid where it was collected. This procedure produces an area map of the
intensities of that specific band plotted as a contour map, where lines
connect the areas of similar value. In these plots, line thickness has been
used to represent the changes in intensity of the absorption bands. The
thickest lines correspond to the areas of strongest band intensity-that
is, the highest concentration in the sample-and the thinnest lines repre
sent the lowest intensities. The intensities are relative to one another,
and the background intensity may not be zero, depending on the base
line in the region.
The method of IR mapping shows potential for the determi
nation of materials and their locations within a cross section sample.
The technique is complementary to elemental mapping with an electron
79
Infrared Analysis Methods
2 1 06
2063
Figure 4.29
A contour map showing the intensity of
the spectral carbonate band ( 1 424 cm-1)
i n relation to its position on the grid where
it was collected. To plot the data as a con
tour map, areas of similar absorbance
��
>c
o
o
a.
en
.�
201 9
1�
-===::�:=: � �����
-
�
�
1 976
1 933
1 890
intensity are con nected with a line. The
heavier the line, the higher the concentra
tion. (Paint cross section from A llegory of
Fortune by Dosso Dossi,
J.
Paul Getty
C=�L-�-
1 803
4846 4885 4924 4963 5002 5041 5080 5 1 1 9 5 1 57 5 1 96 5235 5274 531 3 5352 5391
Museum [x67J . )
X-axis position (11m)
microscope and may be done on the same sample. At this point, the
method has two maj or limitations. The first is its dependence on the use
of specular reflection as an analysis method; this dependence places a
minimum size of 20 x 20 J.lm on the analysis window because of energy
restrictions. Specular reflection can also result in band distortions and
shifts, for which it is difficult to compensate. The second limitation is
that a material cannot be reliably identified based on one IR absorption
band. Thus, additional analyses are required to supplement the map and
provide interpretation. Future computer programs should allow the cre
ation of a map based on the selection of multiple absorption bands that
can help identify specific compounds.
Microspectrophotometer accessories
Several accessories are available for IR micro spectrometers ( Reffner,
Wihlborg, and Strand 1 99 1 ) . One is the grazing-angle obj ective ( see
Suppliers, Spectra-Tech, Inc . ) , which is used for low-angle reflection
measurements of very thin films on polished metal surfaces, as well as
for the detection of monomolecular surface films. Another useful acces
sory is the ATR obj ective ( see Suppliers, Spectra-Tech, Inc.; Bio-Rad
Digilab; Nicolet Instrument Corp.; Bruker Instruments; Graseby Specac;
Bomem International) , which may be used for internal reflection micro
spectroscopy to examine small areas of nonreflective materials nonde
structively ( Fig. 4 . 3 0 ) . Chess provides a good paper on the use of these
two obj ectives ( Chess 1 99 5 ) .
ATR microspectroscopy, a s with the macro version, i s a sur
face analysis technique that requires little to no sample preparation. It
has been shown to be very useful for the analysis of single fibers, hair
and hair coatings, ink on paper, and paint chips ( Bartick, Tungol, and
Reffner 1 994 ) . Different crystals ( internal reflection elements) may be
selected, depending on the type of sample, its hardness, and its refractive
index. ZnSe, germanium, silicon, and diamond elements are available.
80
Chapter
4
Figure 4.30
A Cassegrain reflective optics objective
(left) and a micro ATR objective (right) for
use on an IR microspectrophotometer.
Summary
One of the most versatile and important aspects of IR spectroscopy is
that samples of any form or composition can be analyzed. Selecting the
optimum method for the analysis, however, is not always easy; many
sample preparation methods exist, and the analysis technique chosen
often impacts the spectral results. Transmission analysis methods have
become the de facto standard, because they were the earliest and most
widely used techniques. Most reference spectra are generated by trans
mission methods.
While there is no one technique appropriate for the analysis
of every sample, some methods can be used for most sample types. Many
can be prepared as thin or compressed films on transparent windows,
especially with the aid of a compression cell that uses alkali halide or
diamond windows. The use of a beam condenser or microscope is also
very beneficial to the analysis of the small samples often encountered in
the art conservation field. Sample analysis techniques for IR micro spec
troscopy include mapping experiments used to characterize the composi
tion and position of constituents in nonhomogeneous samples.
Additional Reading
Infrared instrumentation
Ferraro, J . R., and L. J . Basile
1 978, 1 979, 1 982, 1 9 8 5 . Fourier Transform Infrared Spectroscopy. Vols. 1-4. New
York: Academic Press.
Griffiths, P. R., and J . A. de Haseth
1 98 6 . Fourier Transform Infrared Spectrometry. New York: John Wiley and Sons.
Koenig, J . L.
1 992. Spectroscopy of Polymers. Washington, D.C.: American Chemical Society.
Low, M . J . D . , and N. S. Baer
1 977. Application of infrared Fourier transform spectroscopy to problems in conser
vation. Studies in Conservation 22: 1 1 6 .
I nfrared Analysis Methods
81
Reffner, J. A., J . P. Coates, and R. G . Messersch m i d t
1 9 8 7. Chemical microscopy with FTIR microspectrometry. American Laboratory
(April) : 8 6 .
S m ith, A .
l.
1 9 79. Applied Infrared Spectroscopy: Fundamentals, Techniques, and Analytical
Problem Solving. New York: John Wiley and Sons.
W i l lard, H. H . ,
l. l.
Merritt, J r. , and J . A. Dean
1 9 84. Instrumental Methods of Analysis. New York: D. Van Nostrand Co.
Analysis methods
ASTM C o m m ittee
1 9 79. Manual on Practices in Molecular Spectroscopy. Philadelphia: American
Society for Testing Materials.
C h i cago Society for Coating Techn ology
1 9 80. Infrared Spectroscopy Atlas for the Coatings Industry. Philadelphia: Federation
of Societies for Coating Technology.
Griffiths, P. R., and J . A . de Haseth
1 9 8 6. Fourier Transform Infrared Spectrometry. New York: John Wiley and Sons.
Harrick, N. J .
1 9 79. Internal Reflection Spectroscopy. Ossining, N.Y.: Harrick Scientific Corp.
Harrick Scientifi c Corp.
1 9 87. Optical Spectroscopy: Sampling Techniques Manual. Ossining, N.Y.: Harrick
Scientific Corp.
H u mecki, H. J . , ed.
1 9 95. Practical Guide to Infrared Microspectroscopy. New York: Marcel Dekker.
Kortu m , G .
1 969. Reflectance Spectroscopy. New York: Springer-Verlag.
Messers c h m idt, R. G., and M. A. Harthcock, eds.
1 9 8 8 . Infrared Microspectroscopy: Theory and Applications. New York:
Marcel Dekker.
Roush, P. B . , ed.
1 9 87. The Design, Sample Handling, and Applications of Infrared Microscopes.
Philadelphia: American Society for Testing Materials.
S m ith, A.
l.
1 9 79. Applied Infrared Spectroscopy: Fundamentals, Techniques, and Analytical
Problem Solving. New York: John Wiley and Sons.
Wendlandt, W. W., and H. G. Hecht
1 969. Reflectance Spectroscopy. New York: Wiley-Interscience.
Wilks, P. A .
1 9 65. Internal Reflection Spectroscopy. Norwalk, Conn.: Wilks Scientific Corp.
Chapter
5
Spectral Interpretation
Qualitative IR spectroscopy is a valuable analytical tool that allows for
the identification of organic and inorganic materials. Each compound's
IR spectrum contains a substantial amount of information. This informa
tion, along with some patience, skill, and knowledge about a sample's
background, can be used to determine molecular structures successfully,
as well as to characterize unknown materials.
This chapter covers general methods for spectral interpreta
tion and then concentrates on specifics that apply to natural organic
materials, colorants, and mixtures often found in works of art. Spectra
are discussed in terms of their important features. Also included are fac
tors that may affect the interpretation of an IR spectrum, such as its
generation, presentation, and processing. Some special considerations,
cautions, and limitations of IR analysis will be presented in terms of
spectral interpretation.
Infrared Spectra
An IR spectrum displays detector response and is usually plotted in
% transmittance (% T) or absorbance (A, which is the base 10 log of the
reciprocal of T) versus IR frequency ( in wavenumbers [cm - 1 ] ) . A fre
quency of radiation that interacts with the sample produces an absorp
tion band that is characteristic of the energy required for a particular
molecular group transition ( usually a vibrational motion). The collective
position and pattern of these absorption bands designate the combina
tion of molecular groups found in any specific compound.
Absorption bands
The absorption bands in a recorded IR spectrum exhibit three important
parameters: frequency, shape, and intensity. These band attributes are
unique for each individual molecule or material.
Band frequency
The band positions, or frequencies, indicate the presence of certain func
tional groups in a material. Band assignment in the functional group
region ( 4000-1 500 cm - 1 ) is usually straightforward, while assigning a
Spectral I n terpretation
83
band to a specific functional group in the fingerprint region
( 1 500-500 cm- 1 ) may be difficult, since many types of functional groups
absorb at similar wave numbers in this region. Identification of a material
using the fingerprint region is based on the correlation between the peak
pattern of the sample and the peak pattern of a standard material of
known chemical composition. Many aids, some of which are discussed in
this chapter, assist the spectroscopist in the determination of molecular
structures based on band frequencies.
Band shape
The shapes of absorption bands provide information concerning the
group functionality as well as the material purity. All single absorption
bands are, by nature, symmetrical in shape, resembling a normal bell
curve, with a peak maximum and equal wings on each side. Deviations in
band symmetry, such as a slight shoulder or an unusual tail, indicate the
presence of an overlapping band. In a complex molecule, deviations in
band shape may be related to similar functional groups that exist in dif
ferent molecular environments. The presence of asymmetric bands can
also indicate that a sample is a mixture or has been modified, such as by
oxidation. Theoretically, a normal band shape is very sharp. The width
of a band can be increased by inter- and intramolecular interactions, as
well as by overlapping bands. Broad bands, such as those due to hydro
gen bonding or ionic functional groups, are very characteristic. Doublet
bands, often produced by crystalline lattice effects, are also useful in
characterizing a material.
Band intensity
The relative intensity of a band, in comparison to the other bands in
the spectrum, provides information on the amount and type of a specific
functional group present in a molecule. Functional groups that are
responsible for a large change in the dipole moment of a molecule
carbonyl groups, for example, will produce very intense absorption
bands. Of the three band attributes, band intensities are most likely to
show deviations related to sample preparation.
These three attributes define each band in a spectrum. Any
two identical samples prepared under identical conditions will produce
identical spectra. Any deviation-in band frequency, shape, or inten
sity-between the two spectra indicates a difference between the two
samples. While differences may be due to sample composition, they may
also be due to sample preparation, spectral plotting format, or instru
ment parameters. While the last three factors do not change the molecu
lar vibrations in the sample, they can cause superficial changes in the
character of the spectra that need to be accounted for in the spectrum
interpretation. Every good spectrum, especially a reference spectrum,
should include information on conditions of analysis and instrumental
parameters; this information allows the spectroscopist to make a knowl
edgeable comparison.
84
Chapter
5
Plotting format
The interpretation of an IR spectrum is based directly on visual inspec
tion of the spectrum, on recognition of characteristic features, and on
comparison of the spectrum with reference spectra. Visual cuing is
directly dependent on the plot of the spectrum. Several types of spectral
presentation formats may be found in j ournal articles, reference books,
and spectral libraries. To the novice spectroscopist, these may seem con
fusing and not comparable. But in fact, the spectra are consistent and
reliable and, with a little practice and an understanding of the various
plotting formats, they can be visually compared. Examination of the axis
labels will quickly provide the mode and scales of the plot selected in any
particular case.
Figure 5 . 1 displays the same IR spectrum of linseed oil in
four commonly used plotting formats. Close examination of each plot
may be needed in order to understand that, indeed, these are all plots
of the same material. The most noticeable difference among these four
spectra is that, in some instances, the bands or peaks descend (transmit-
Linseed oil ( X 2 expansion)
4000 3600 3200
2800 2400
2000
1 800
1 600
1 400
1 200
1 000
800
600
� V v,,;'V :-0� ��Q)
�
,��
� 1/01 T �t'�<J)�
90
80
70
A
60
==
-B b II
c +
r1
D c--- �I VI ·tr------ c--I'-.-.. J'-./-- ! -'" . -�
3400
3000
Linseed o i l (linear)
1800
2200
2600
-.
---
1000
1 400
�<J)
50
40
Wavenumber (em ' )
3800
600
90
f
80
--
6
8
Linseed oil
12
10
50
40
16
14
�m
Linseed oil (X2 expansion)
4000
Figure 5.1
The same spectrum of linseed oil shown in
four different plot formats. The format of
plot A is generally considered standard.
The format in plot C is no longer com
monly used.
3600 3200 2800
-"
.--
_.
it!
2400 2000 1 800
1 600
1400
1 200
-.-
:1\
Wavenumber (em- ' )
-- 0.40
0.30
----- -
1 000
800
Q)
()
70 E
60
Wavenumber (em- ' )
4
()
600
0.20
0.10
.0<t:�
Q)
()
£
Spectral Interpretation
85
tance, Fig. 5 . 1 , spectra A-C ) , and in some they ascend (absorbance, Fig.
5 . 1 , spectrum D ) .
The absorbance mode i s used for quantitative analysis and
other mathematical processing. According to Beer's law, the intensity of
each band is directly proportional to the concentration of the absorbing
species-such that there is a linear relationship between band intensity
and concentration. This linear relationship applies only to spectra in
absorbance mode; in transmittance mode, there is a logarithmic relation
ship between band intensity and species concentration. Besides quan
titative analysis, other computer spectral manipulation methods-such
as subtractions, transformations ( Kubelka-Munk, Kramers-Kronig),
deconvolutions, and spectral searches-are done with the spectra in
absorbance . This may be a hidden process, since computers can instanta
neously switch between absorbance and transmittance. When one mode
of display, such as transmittance, is selected for the spectrum, the com
puter will perform any conversion necessary as part of the processing
and quickly return the processed spectrum to the screen in its original
mode (i.e., transmittance) .
Spectra plotted i n transmittance are shown i n Figure 5 . 1
(A-C ) . This mode has been historically used for IR spectra a n d i s still the
most commonly seen format for reference spectra. A transmittance spec
trum is the ratio of the radiant power transmitted by a sample to the
amount of incident radiation on the sample. Prior to the use of Fourier
transform IR spectrometers ( FT-IRs ) , this was the value read directly
from the detectors and plotted. Transmittance mode has an advantage
for the viewing and comparison of spectra, because the logarithmic
scale amplifies the intensity of the weak bands while keeping the highly
absorbing bands on scale.
With the advent of the FT-IR and its integral computer, the
operator may select any mode for viewing, plotting, and calculation. The
computer can quickly and easily convert from one format to another.
Since it will often be necessary to compare the hard copy (printed form)
of spectra in different formats, however, it is important to become famil
iar with the visual and mental gymnastics required to convert between
absorbance and transmittance. The scales should always be checked,
because there are some spectra that have been plotted in transmission
but then inverted, with the bands ascending; conversely, some spectra are
plotted in absorbance units, with the peaks descending. This incorrect
and confusing practice occasionally appears in publications.
Varying abscissa scales are also seen in IR spectral plots .
Visible light, when measured in wavelengths, is typically reported in
microns ( /-Lm ) . For IR spectra, the corresponding use of the linear scale
of wavelengths in microns ( 2 .5-1 6 . 6 /-Lm; see Fig. 5 . 1 , spectrum C) is a
simple representation and easily related to the other familiar spectral
measurements, such as UVNis, that are used in spectroscopy. Older,
prism-type dispersive instruments produced plots with linear wave
lengths; this practice is now considered obsolete.
The surge in the generation of IR spectral libraries occurred
with the grating-type dispersive spectrophotometer (without computer ) .
86
Chapter
5
The output of this dispersive spectrophotometer was linear in wavenum
bers or frequency (cm- l ; see Fig. 5 . 1 , spectrum B ) . Wavenumbers are
reciprocally related to wavelength (e.g., 1 000 cm- l
=
1 0 /Lm) and are
considered more accurate for spectral presentation, since the energy of a
vibrational mode is a function of frequency and not of wavelength.
In a linear wavenumber representation, however, the finger
print region of the spectrum ( 2000-500 cm- l ) is compressed and difficult
to see. Thus, it became a standard procedure to switch the speed of the
chart recorder at 2000 cm-l to a slower setting; this practice resulted in
a x 2 scale expansion of the fingerprint region. Thus, the plots have a lin
ear scale between 4000 and 2000 cm-t and a double-size linear scale
between 2000 and 500 em- I , as shown in Figure 5 . 1 , spectra A and D .
Plots that use a x 4 scale expansion may occasionally b e found.
Because of the large number of reference spectra generated
in the format shown in Figure 5 . 1 , spectrum A (i.e., most published
libraries and reference books ) , this format has been termed standard. The
spectrum is plotted in transmittance, with a linear wavenumber ( cm - l )
scale containing a x 2 expansion i n the region o f 2000-500 cm- l .
Instrument configuration
Several possible options for instrument configurations exist. While these
options do not change molecular absorption bands, they may change the
appearance of the spectra. IR mercury-cadmium-telluride (MeT) detec
tors are available in narrow, medium, and wide ranges. The choice of the
detector affects the sensitivity and the spectral range of a given spectrom
eter, with the narrow-range detector providing the highest sensitivity.
Thus, the scale of a spectrum may range from 4000 to 700 em- I , or from
4000 to 500 em- I , depending on the type of detector deployed.
The resolution, or number of data points per spectrum, is
selectable on FT-IR instruments. A higher-resolution spectrum will con
tain more data points and will thereby provide better representation and
separation of the true absorption bands. To collect a higher-resolution
spectrum, the instrument resolution setting must be changed to a lower
wavenumber, since this parameter indicates the interval for data collec
tion. For example, an instrument set at a resolution of 1 cm- l will col
lect a data point every 1 cm - t . Thus, for a spectrum collected over the
range of 4000 to 800 em-I, there will be a total of 3200 data points.
An instrument set at 4 cm-l will only collect one-fourth as many, or
800 data points. Therefore, a resolution of 1 cm- l is higher than a reso
lution of 4 cm- t .
A commonly used resolution i s 4 cm- t • However, most instru
ments are capable of at least 1 cm-t resolution, while many digitized
library spectra were collected at 8 cm- t . Spectra produced at the finer
resolutions (i.e., 1 em- l or below) may contain a distinct band in an area
that only appears as a shoulder in a spectrum collected at a lower resolu
tion. Interest in studying the fine spectral details is one reason for using
the higher resolutions, but a possible effect on the character of the spec
trum should be kept in mind when spectra recorded at different resolu
tions are compared. Additionally, higher-resolution spectra require more
87
Spectral Interpretation
time for data collection, and since their files are larger, they also require
more disk storage space. Most search routines recommend that the reso
lution of the search spectrum stay within a factor of 2 of the resolution
of the library spectra.
Qualitative Analysis
There is no one set of procedures for the identification of unknown mate
rials by IR spectroscopy. Nor is it possible to identify every material by
IR spectroscopy alone. However, with a good-quality spectrum, it is pos
sible to screen a sample and to obtain the general classification of a mate
rial by its major functional groups. Additionally, and sometimes most
important, it is possible to rule out several types of materials based on
the absence of major functional groups. Thus, it is essential to understand
the analytical question framed for each sample prior to spending a
significant amount of time on the interpretation of a spectrum.
In general, the interpretation of a spectrum of an unknown
material requires the identification of functional groups in the spectrum,
along with direct comparison to reference spectra. Several useful tools
(correlation charts, flow diagrams, computer search routines, etc . ) are
Figure 5.2
available to speed up the process. One possible, stepwise approach for
An identification scheme for the systematic
the identification of an unknown spectrum is presented in Figure 5 . 2 .
interpretation of I R spectra. Many aids are
A simple spectrum may be identified within a few steps, while a complex
avai lable to assist in interpretation. The
mixture may require multiple passes through the procedure.
final step for identification is always visual
comparison of the sample spectrum to
Spectral quality
known reference spectra.
The first step in spectral interpretation is the determination of spectral
quality. Many hours can be wasted interpreting a poor-quality spectrum
C ::>
that misrepresents the true absorption band positions, shapes, and inten
Begin
sities. Table 5 . 1 lists some requirements for a good IR spectrum. Most
Visual
comparison
with
collections
of
reference
spectra
(match)?
10
material class?
(a) Functional group analysis
(b) Correlation charts
(c) Flow diagrams
Summary
yes
(a) Does match correspond to
information known about piece?
(b) Can discrepancies be justified?
(c) Are possible errors eliminated?
(d) Has the initial analysis question
been answered?
yes
no
no
Alternate
analysis method
88
Chapter
5
Table 5 . 1
Req u i rements for a good -quality I R
spectru m .
Specifi cations of a
good-qual ity spectrum
Parameter
flat and level, positioned
near 1 00 % transm ittance
Baseline
(0.0 absorbance)
Possible problems
res u lting in deviations
from specifications
sample is poorly ground;
sample surface is not flat;
background does not match
sample spectrum
Noise
maximum noise level no
greater than 1 % of
strongest band
sample too small; i nsufficient
nu mber of scans collected
I ntensity
signal no stronger than
1 0 % transm ittance
( 1 . 0 absorbance)
sample too concentrated ;
sample too thick
Extraneous bands
water vapor and carbon
dioxide should be less than
2% transm ittance
(0.1 absorbance)
background does not m atch
sample spectru m ; instrument
is poorly purged
poor spectra are the result of improper sample preparation techniques
that may be corrected by preparing the sample again. Occasionally an
alternate analysis method, such as reflection versus transmission, may
be required to eliminate a problem. In cases in which the sample cannot
be reanalyzed, computer routines may be used to manipulate spectra into
a better form. Any alteration of spectra must be performed with cau
tion-and only done as a last resort, as it has the potential to produce
misleading results.
Examination of the spectrum baseline-that is, the portion
that has no absorption bands-can provide information on spectral qual
ity. One quality check for the spectrum is whether the baseline is flat,
level, and positioned near 1 0 0 % T ( 0 . 0 absorbance). Shifting of the base
line above or below the proper position occurs when the intensity of the
background spectrum does not correspond to the sample spectrum. With
IR microspectrophotometers, this shifting may occur if the aperture size
for the background is different from that of the sample. The baseline
can also be shifted when a sample is black, since all wavelengths will be
strongly absorbed.
A sloping baseline is usually an indication that the radiation
has been diffracted andlor scattered as it passed through the sample. This
problem can occur if the particles in a potassium bromide (KBr) pellet
are not ground finely enough or if the sample surface of a thin film on a
window is not flat. Figure 5 . 3 shows a spectrum with a sloping baseline
before and after the application of a computerized baseline correction
routine. Such routines attempt to level the baseline to 1 00 % T (0.0
absorbance ) . Linear and multiple-point correction curves are available.
Any spectral alteration of the digitized data by baseline correction should
be carefully examined for changes in the relative intensities of the
absorption bands.
Examination of baseline noise level is also used as a quality
check. The signal-to-noise ratio of a spectrum is calculated by comparing
the intensity of the noise level at the baseline to the intensity of the
89
Spectral I nterpretation
1 00
Sloping baseline
90
Q)
u
c
(1j
:t:if.�:
80 ,
E
(/)
c
(1j
70 '
�"'''k
60 '
3500
1 05
2000
2500
Wavenumber (cm- 1 )
3000
1 500
1 000
Baseline corrected
�c \�\4r'r4
.��E
�tt.�
1 00
95
Figure 5 . 3
An I R transm ittance spectrum for a protein
before and after baseline correction . A
sloped basel ine is often caused by diffraction of light when it passes through the
sam ple. Baseline correction routines
attempt to level the baseline at 1 00 %
transm ittance. Relative absorption band
intensities may be altered by baseline
correction.
(I
Q)
u
c(/)
(1j
if.
90
85
80
75
70 ,
3500
3000
2000
2500
Wavenumber (cm- 1 )
1 500
1 000
strongest absorption band. This calculation is termed the signal-to-noise
ratio. The higher the signal-to-noise ratio, the better the quality of the
spectrum. A very small sample will often produce a spectrum with high
noise levels. The best ways to minimize high noise levels are to run a
larger sample or to collect and average more scans. If this is not feasible,
a smoothing routine may be applied to decrease noise levels. Figure 5 .4
shows an IR spectrum before and after smoothing to a 5 0 % level.
Smoothing effectively decreases the resolution of the spectrum, however,
and minor absorption bands or shoulders may disappear.
The most intense absorption band in the spectrum should
be between 1 0 %T and 6 5 % T ( 1 .0-0 .2 absorbance). The purpose of an
intensity check is to ensure that the sample concentration or thickness is
optimum. When a sample is too thick, the strongest absorption bands
with a transmittance greater than 1 0 % T ( 1 .0 absorbance) will " bottom
out," and information regarding band position, shape, and relative
intensity will be lost. For accurate quantitative work, such as spectral
90
Chapter
5
Un smoothed
subtraction, the optimum absorption range is smaller, with an absorption
maximum no greater than 20% T ( 0 . 7 absorbance; see " Subtraction tech
niques, " p. 1 24 ) . When the strongest absorption band is less than 6 5 % T,
the concentration of the sample is low, and some weak bands may not be
easily recognized. When comparing the spectrum of a weak sample with
a reference spectrum, a spectroscopist can compensate for the feeble
bands, but a computer search routine may have difficulty.
Another important consideration is whether the instrument
and its sample compartment are purged with dry, carbon dioxide
( C02 )-free air. Vapor-phase water (H2 0 ) produces small, sharp absorp
tion bands in the regions from 4000 to 3000 and 1 8 00 to 1 600 cm- 1 ,
while the predominant CO 2 absorption band occurs a s a doublet at
2340 cm-1 ( Fig. 5 . 5 ) . Purged instruments will eliminate, or at least
diminish, the appearance of these bands. Spectra from nonpurged instru-
91
Spectral Interpretation
Water
Water
vapor
vapor
()�
oR.
OJ
c
co
t:
E
UJ
c
co
Figure 5.5
An IR transm ittance spectrum of room air
containing water vapor and carbon diox
co
ide. Most instruments are purged with dry,
CO2-free air to m i n imize contributions due
4000
3600
3200
2800
2400
2000
1 800
1 600
1 400
1 200
1 000
800
600
Wavenumber (cm- 1 )
to these absorption bands.
ments will show small CO 2 and H2 0 bands if the atmosphere for the
background spectrum and the sample spectrum are similar. However, if
the room air changes between the background and sample spectral runs
because of drafts or human presence, the spectrum may exhibit stronger
atmospheric bands. While usually open to the atmosphere, the sample
stage area of most FT-IR microspectrophotometers can also be partially
purged with the use of a removable shroud placed on the objective lens.
Visual comparison
Visual examination of the spectrum involves the direct human compari
son of a sample spectrum to reference spectra of known materials. The
visual pattern recognition procedure, while simple, is very important,
because it provides definite identification. It is also very time-consuming,
since well over 200,000 published reference spectra are available for
comparison. Further, differences between spectra of similar compounds
are often quite small. Time needed for interpretation can be substantially
reduced by narrowing the examined number of spectra based on the
sample's physical characteristics, as well as on identification of major
functional groups present in the spectrum. The experienced spectro
scopist will occasionally be able immediately to recognize a spectrum
of a material previously encountered. In any case, the visual comparison
of the unknown spectrum to a reference spectrum is always the last step
toward verification of an unknown material.
Appendix I lists several significant books, articles, and digi
tized databases containing IR spectra collections. These reference collec
tions are very comprehensive for modern materials. However, they
include few spectra of natural materials, such as those used historically
in artist materials. In an attempt to fill this void, more than twenty
museum and conservation laboratories j oined together to combine their
92
Chapter
5
collections of spectra into a single IR spectral library of artists' materials
( see Appendix I, Infrared Users' Group 1 99 5 ) . Additional compilations
of reference spectra prepared specifically for use in conservation are the
Gettens Collection ( see Appendix I, Snodgrass and Price 1 99 3 ) and
Infrared Spectra of Naturally Occurring Minerals ( see Appendix I, Price
and Carlson, forthcoming) . Many of the compilations are available in
digitized form on computer disk, for convenient addition to the digital
spectral library of any FT-IR.
Computer libraries
The coupling of high-performance computers with IR spectrophotometers
allows for the rapid processing of spectra together with the storage of
large numbers of IR reference spectra. Many IR operating programs also
provide spectrum-structure correlations, automatic spectral interpreta
tion, and searching of large stored libraries of IR spectra. This greatly
reduces the time needed for the visual comparison of an unknown spec
trum to reference spectra.
Computer library search programs are typically based on cal. culation of the difference in peak position and intensity in the unknown
spectrum versus those of known spectra. Most software library programs
have an option for more than one search algorithm for distinguishing
similarities between spectra. Each algorithm performs the calculations
slightly differently. In order to determine the variations between these
programs and the significance of the match (hit) quality, a known mate
rial may be analyzed and its spectrum searched in the library multiple
times with different search options or parameters.
No matter how good the software is, it can never replace the
j udgment and visual skills of a well-trained analytical chemist. The list of
hits from the library search is, at best, only a starting point for the visual
comparison of the unknown sample's spectrum with reference spectra.
Generally, a high hit index means that the spectra match well, but this is
not always the case. In some programs the hit with the best match qual
ity is 1 00, while for other programs it would be 0.000. For example, a
hit index of 0.0 7 1 6 would be an excellent match if obtained on a scale
where 0.0000 is a perfect match, and a typical match of 0.2000 is con
sidered a good fit. A computer program may find a hit that has similar
bands except for one or two. If these are significant bands, then the spec
troscopist can eliminate that hit as a possible choice. A computer may
also be misled by sample or reference spectra with sloping baselines or
with extraneous bands from contamination. A j udgment call by an expe
rienced spectroscopist is needed to determine the importance of spectral
features and deviations. The quality of the spectra in the library, as well
as the spectrum of the unknown sample, are critical to obtaining credible
results. Spectral history-such as analysis method, run parameters, and
use of correction routines-should be known for both the unknown spec
trum and those in the computer library.
Characterization of the sample type (polymer, mineral, sol
vent, etc. ) helps in the selection of the computer libraries to be searched.
Spectral Interpretation
93
Since numerous libraries are available, search time may be minimized by
limiting the number of libraries. When a library does not contain refer
ence materials in the same chemical class as the unknown sample, it is not
likely that the computer will obtain a good or even a reasonable match. In
particular, search programs are very ineffective at characterizing material
mixtures, because most libraries are composed of pure materials.
The results of a computer search routine are totally dependent
on the searched spectral library. The best library is often one that con
tains reference spectra generated on one's own instrument. These spectra
tend to match better, because the reference materials were prepared and
analyzed in a manner consistent with the unknown sample. They are
also more likely to contain materials related to the sample . It is time
consuming, however, to generate the large number of spectra required to
compile a comprehensive library. Thus, an active exchange of IR data and
spectral libraries between labs that are conducting similar experiments is
the second-best choice for developing useful spectral libraries.
For the most part, IR spectra do not vary significantly from
instrument to instrument. This is particularly true for FT-IRs, since they
have the advantage of internal wavelength calibration. IR data exchange
has been facilitated by the development of a universal data format by the
Joint Committee on Atomic and Molecular Physical Data Exchange; the
format is known by the committee's acronym JCAMP.DX ( McDonald
and Wilks 1 9 8 8 ) . Most IR manufacturers supply programs that use this
standard form for external data exchange. Additionally, some stand
alone computer programs, such as Lab-Calc ( see Suppliers, Galactic
Industries Corp . ) , are available for conversion of spectra to and from
the JCAMP.DX format. One commercial lab offers spectral searches on
digitized spectra ( see Suppliers, Photometries Ltd . ) .
Spectral region examination
Since the functional groups for a sample are usually not known, interpre
tation is best started by dividing the spectrum into several frequency
regions. The presence and absence of absorption bands in each region are
then used to characterize the sample ( Smith 1 9 79). Thus, starting with
the frequency regions at the high-wavenumber end, an unknown spec
trum may be divided as follows:
OH-NH region (4000-2600 em-I)
Hydroxyl groups generally produce a broad-envelope-type band centered
around 3400 cm- l . This band can be misleading, because absorbed water
on the sample or on the alkali salt substrate will also produce an O-H
band. Hydrogen bonding can change the band position and shape. The O-H
band for carboxylic acids is very broad and centered about 3400 em-I,
while the water of hydration for clay produces very sharp bands at
3700-3500 cm- l . N-H stretching bands also occur in this region, with their
center near 3350 cm- l . N-H bands are usually sharper than O-H bands.
For a natural product sample, the absence of bands in this region shows
that the sample does not contain any carbohydrates or proteins.
94
Chapter
5
C-H stretching region (3200-2800 em- I)
C-H stretches from aromatic and vinyl hydrocarbons occur at 3 1 00-3 000
cm- I . C-H stretches for methylene groups occur near 2925 (asymmetric)
and 2 8 5 0 ( symmetric) cm-I, with the corresponding C-H stretches for
methyl groups near 2962 and 2 8 72 cm- I . Thus, with 3000 cm-I as an
imaginary dividing line, the hydrocarbon stretches for unsaturated carbon
groups occur at higher wavenumbers, and the C-H stretches for saturated
carbon groups occur at lower wavenumbers. Waxes, oils, and natural
resins, for example, have strong hydrocarbon stretches.
Window region (2800-1 800 em-I)
This is usually a baseline region where few absorption bands occur. The
most common band is for atmospheric carbon dioxide ( doublet at
2340 cm- I ) . Other bands that occur in this region are a carbon triple
bond near 2 1 20 cm- I , nitrile stretch near 2240 cm-I, isocyanate stretch
near 2265 cm- I , and thiocyanate near 2 1 60 cm- I . Prussian blue, ferric
ferrocyanide, has a strong absorption band in this region.
Carbon double bond region (1 800-1500 em-I)
The highly polar carbonyl bond produces a strong absorption band at
1 8 50-1 650 cm-I that varies with carbonyl type-for example, 1 740 cm-I
for ester, 1 7 1 0 cm-I for ketone. The carbonyl band for the amide I group
is shifted down to about 1 650 cm-I, with corresponding amide II
( 1 5 50 cm- I ) and amide III ( 1 450 cm- I ) bands occurring in stair-step-type
intensities. In carboxylic acid salts, the asymmetric stretch for the carbon
oxygen bonds occurs near 1 650-1 540 cm- I . A carbon double bond
stretch occurs about 1 640 cm- I . Aromatic carbon-carbon stretching
vibrations occur at 1 600-1 5 8 5 and 1 500-1400 cm- I .
Fingerprint region (1 500-500 em- I)
Most functional groups also have bands in the fingerprint region. The
fingerprint bands, when taken in combination with the group frequency
bands, can confirm an assignment. The absorption pattern in the finger
print region is frequently complex, with interacting vibrations and over
lapping bands. It is, however, unique for each material and thus most
valuable for specific identifications made by direct comparison to refer
ence spectra.
Negative interpretation
Just as the presence of functional group bands can be used to select
potential matches, the absence of a functional group band is used to
eliminate potential groups of materials. Entire chemical classes of materi
als can be ruled out j ust on the absence of one or more basic group fre
quencies, such as hydroxyl, hydrocarbon, carbonyl, and amide. This key
factor should not be underestimated. The positive identification of a
material can never be based on the presence of j ust a single band,
because multiple materials can produce similar bands. However, the
absence of an absorption band is unambiguous: if one absorption band is
not present, then that material is not present. For example, if the spec-
Spectral Interpretation
95
trum for a paint binder does not have a carbonyl band between
1 75 0 and 1 650 cm- I , then it does not have any measurable amounts of
oil, egg yolk, glue, natural resin, acrylic, alkyd, or any number of other
synthetic resins that contain a carbonyl group. This result, in itself, may
be sufficient to answer the analytical question about the sample, thus
freeing important analysis time for other samples.
Spectra-structure correlations
An essential part of the spectral identification process is the examination
of absorption band frequency to determine corresponding functional
groups. Table 5 .2 provides a list of molecular functional groups and their
corresponding absorption band frequencies.
Hydrocarbons: Aliphatic
Commonly found in spectra of most organic materials, the C-H stretch
ing vibrations occur in the region of 3000-2 8 00 cm- t . As seen in Figure
5 . 6 , a spectrum of paraffin, the methyl group ( CH3 ) vibration produces
two small bands at 2 9 62 and 2 8 72 cm-I, because of the asymmetric and
symmetric stretching modes. The methylene groups ( CH2 ) produce sharp
asymmetric and symmetric stretching vibrations at 2926 and 2 8 5 0 cm- t .
Table 5.2
The bending vibrations for the CH3 groups are found at
1 4 5 0 and 1 3 8 0 cm-t for asymmetric and symmetric, respectively. The
Some im portant group frequencies.
in-plane bending or scissoring band for CH2 is found at 1 465 cm- t . In
Functional group
Formula
Associated absorption band frequencies
Hyd roxyl
-OH
Hyd roxyl groups generally produce a broad-envelope-type band centered at 3400 cm- 1 .
Hyd rogen bonding can change position and shape.
U n satu rated CH
- H -<j>C
- H -C=C-
CH stretches from aromatic hydrocarbons occur at 3 1 00-3000 cm-1 . C H stretches from a
carbon double bond occur about 3030 cm-1 .
Ali phatic CH- methylene
CH stretches for methylene groups occur near 2925 (asymmetric) and 2850 (symmetric)
cm - 1 . The vibrations for bending occur near 1 465 cm-l , for rocking, ca. 730 cm- 1 (only for
CH2 sequences greater than 4 and may be split in solids) .
Ali phatic CH- methyl
-CH 3
CH stretches for methyl groups occur near 2962 (asymmetric) and 2872 (symmetric) cm-1 .
The vibrations for CH bending occur near 1 450 and 1 3 80 cm-1 .
Carbon-carbon
m u ltiple bonds
-C=C-C = C-
A carbon dou ble bond stretch occurs ca. 1 640 cm- 1 and a carbon triple bond near
2 1 20 cm- 1 . Aromatic carbon stretching vibrations occur near 1 600 and 1 500 cm-1 . Out-of
plane bending mode vibrations may produce strong sharp bands at 1 000-650 cm-l , depend
ing on the pattern of su bstitutio n .
Carbon-n itrogen
-C=N
- N =C=O
-S-C=N
A nitrile stretch occurs near 2240 cm-1 , an isocyanate stretch near 2265 cm- 1 , and a
thiocyanate near 2 1 60 cm- 1 .
Carbonyl
- c =o
-c-o-
The highly polar carbonyl bond produces a strong absorption at 1 850-1 650 cm- 1 that varies
with carbonyl type-e .g., 1 740 for ester, 1 7 1 0 for ketone.
Amide
-CON H -
N-H stretch about 3350 cm-1 . Amide I occurs near 1 650 cm - l , amide II near 1 550 cm -l , and
amide I I I near 1 450 cm-1 in stair-step-type intensities.
Acid salts
-C02-
Asymmetric stretch for the carbon-oxygen bonds occurs near 1 650-1 540 cm - l , depen ding
on structure.
Carbonate
-C0 3 =
Broad stretching band near 1 450 cm-1 with sharp bands at 900-700 cm-l , depending on
cation.
Carbon -oxy gen
C-O stretch occurs at 1 200-1 000 cm- 1 ; varies with hydrogen bonding and molecular
structure.
96
Chapter
5
.J
.
/
CH3 bending
CH2 rocking
C H2 bending
7
4000
3600
3200
C H2 stretching
2800
2400
2000
1 800
1 600
1 400
1 200
1 000
800
600
400
Wavenumber (cm- 1 )
Figure 5.6
long-chain hydrocarbons, with more than four methylene groups, there is
An I R transmittance spectrum of paraffi n .
also an in-plane rocking band that is found near 730 cm- l . In solid semi
crystalline materials, such as paraffin and beeswax, the absorptions
appear sharper, with characteristic peak splitting forming doublets at the
methylene absorption positions. Other weaker methylene bands are
observed in the 1 3 50-1 1 5 0 cm- l region.
Hydrocarbons: Aromatic
Aromatic C-H stretching bands occur between 3 1 00 and 3000 cm- l . The
strongest, and sometimes most informative, bands in the spectra of aro
matic compounds occur in the low-wavenumber range between 1 000 and
655 cm- l . These strong absorption bands result from the out-of-plane
bending vibrations of the ring C-H bonds. The absence of any major
bands in this region generally shows that the material is nonaromatic.
Skeletal vibrations from the C-C interactions in the ring absorb in the
1 600-1 5 8 5 and 1 5 00-1 400 cm- l regions. A spectrum of polystyrene,
seen in Figure 5 . 7, illustrates these absorptions.
Alcohols and hydroxyl absorptions
c-o
The characteristic bands observed in the spectra of alcohols result from
O-H and
stretching vibrations. These functionalities are susceptible
to hydrogen bonding, which produces broad IR absorption bands.
The O-H stretch generally occurs from 3600 to 3200 cm-l. The C-O
absorption in alcohols occurs from 1 2 6 0 to 1 000 cm- l . Other weaker,
c-o
O-H bending vibrations may be seen at 1 420 to 1 3 3 0 cm- l . Figure 5 . 8
shows a spectrum o f honey, a complex sugar containing multiple
and O-H stretches.
Carbonyls: Aldehydes, ketones, and esters
Ketones, aldehydes, acids, esters, anhydrides, and ami des show a strong
carbonyl ( C = O ) stretching absorption in the region of 1 8 70-1 640 cm- l .
The carbonyl band has a relatively constant position and high intensity,
97
Spectral Interpretation
I nterference fringes
Q)
t='.=oR.()c'"'"
'"c
E
Overtones
Aromatic C-H
stretching
3600
4000
� .>
2800
3200
Ring
deformation
Aliphatic C-H
stretching
2400
Aromatic ring
C=C stretching
2000
1 800
�
1 600
/
C-H bends
1 400
1 200
1 000
800
400
600
Wavenumber (cm- ' )
Figure 5.7
which makes it one of the easiest bands to recognize in the IR spectrum.
An IR transm ittance spectrum of
The exact position of the C = O stretch is determined by its environment in
polystyrene.
the molecule. A carbonyl in a ketone usually occurs at 1 720-1 690 cm-I,
while a carbonyl band in an ester usually occurs at 1 750-1 730 cm- t . The
carbonyl groups in aldehydes absorb near 1 740-1 720 cm- t . The adjacent
C-O stretching vibrations found in esters and aldehydes occur between
1 400 and 1 000 cm- t . Ketones also have weak backbone stretching and
bending vibrations in this region. Figure 5.9 shows a spectrum of polyester.
Carbonyls: Amides
The spectra for primary and secondary amides contain a strong carbonyl
absorption band in the region of 1 65 0 cm-I, called the amide I band.
Figure 5.8
Secondary amides display an additional band near 1 5 5 0 cm- I , called the
An IR transmittance spectrum of honey.
amide II band, that is a combination of C-N and N-H vibrations. A C-H
c
Q)��()'"E'"c
t-
C-H stretching
oR.
\
CoO stretch
4000
3600
3200
2800
2400
2000
1 800
1 600
Wavenumber (cm- ' )
1 400
1 200
1 000
800
600
400
98
Chapter
5
Aromatic C=C
Q)
u
c
co
""I-�ift
Aliphatic C-H
stretching
E
(J)
c
v
C-H bending
�
c=o stretching
4000
3600
3200
2800
2400
2000
1 800
1 600
1 400
1 200
C-O stretching
1 000
800
600
400
Wavenumber (cm- 1 )
Figure 5.9
An I R transmittance spectrum of polyester.
bending vibration occurring near 1 450 cm-1 has sometimes been called
the amide III band. The relative intensities of the amide I, II, and III bands
in polyamides (protein, nylon, etc.) occur in a stair-step pattern. The
asymmetrical and symmetrical N-H stretching vibrations occur near 3350
and 3 1 80 cm- I , respectively. Hydrogen bonding may broaden the bands,
giving the appearance of one band, although they are usually sharper than
O-H bands. Often a stronger O-H band overlaps this region, and the N-H
stretches appear as shoulders or peaks on the broader O-H band. Figure
5 . 1 0 shows a spectrum of gelatin, which exhibits the typical primary and
secondary amide patterns seen in proteins.
Figure 5 . 1 0
An I R transm ittance spectrum o f gelatin.
Q)
u
c
co
""�ift
E
f/)
c
co
"
__
4000
3600
3200
Aliphatic C-H
stretching
N-H
stretching
2800
2400
2000
1 800
1 600
Wavenumber (cm- 1 )
N-H bend with C-N stretch (amide I I )
1 400
1 200
1 000
800
600
400
99
Spectral Interpretation
Correlation charts
Over the years, many researchers have done extensive studies to deter
mine the absorption band ranges of specific functional groups. This
information has been compiled into correlation charts, several of which
may be found in the literature. A simplified version of a correlation chart
is shown in Figure 5 . 1 1 . The lines for each functional group indicate the
most probable range for the absorption band. The precise wavenumber
at which a specific group absorbs is dependent on its molecular environ
ment and its physical state.
One limiting factor to correlation charts is that they represent
only the strongest, most characteristic bands. Other important informa
tion used to identify an unknown spectrum, such as band shape and
intensity, is not incorporated in the chart. The correlation chart is best
used to classify the functional groups in a compound structure for only
the major absorption bands, since minor bands may be due to vibrations
not shown on the chart.
4000 3600 3200 2800 2400 2000 1 800 1 600 1 400 1 200 1 000
Hydroxyl
Hydrocarbons
Aliphatic CH2
Aliphatic CH3
Aromatic CH
Vinyl CH
Carbon-carbon
C=C
C=C
Carbonyl, C=O
Ketones
Aldehydes
Esters
Acids
Carbon-oxygen
Alcohols
Ethers
Amides
Primary
Secondary
Figure 5.1 1
The general range of major absorption
bands for specific functional groups. This
chart can help i n the selection of groups
of materials for further examination by
Amines
Primary
Secondary
Organic salts
Formates
Acetates
direct spectral comparison. Since the figure
Oxalates
does not depict exact band position or
Stearates
intensity and does not include minor
Cyanides
bands, it cannot be used as a sole means
of identification (s = strong; m = med i u m ;
b = broad ) .
,b
I!
I, I"jI
I bI_
iI, 'I
Ii
_I
,I, I I
:I
,
- - _ ....
,
II,
,, ,
1
, ,
,
b
-,
,-: I'-� ,' I
-I t-'I, ,' I. b_ :,, II
I:
I Ii �I I - I
I�t I ! : I I I I
_
s
1
m
-
r
I
I
,
:I
, ,
'I
-
, ,
_
"
600
Ii
I III
II I
800
�
IT
4000 3600 3200 2800 2400 2000 1 800 1 600 1400
Wavenumber (cm- 1 )
I I'
1 200 1 000
800
600
1 00
Chapter
5
Identi fication of Material s U sed in Art and Art Conservation
A variety of natural and synthetic materials have been used in creating
works of art. Though ranging from acrylics to polysaccharides and from
carbonates to oxides, the classification, if not the specific identification,
of these materials in their pure form, as well as in simple mixtures, is
well within the realm of IR spectroscopy. Appendix II provides reference
IR spectra for many materials used in art and art conservation.
Natural organic material s
Natural products, derived from plants and animals, are rarely pure
materials; rather, they are mixtures of many components ( maj or, minor,
and impurities), because of the number of reactions that occur simulta
neously in biological systems. The components may range in complexity
from simple molecules to multicomponent mixtures of organic and inor
ganic compounds. A mixture containing slight variations of many com
ponents produces an IR spectrum with some broad, ill-defined, and
overlapping bands, especially in the fingerprint region. The presence of
ill-defined bands indicates that a material is a mixture and possibly a
natural product.
Flowchart for natural organic materials
For identification purposes, natural products encountered by analytical
chemists working in the art conservation field may be grouped into the
following classes that contain similar IR active functional groups: resins
(tree ) , resins ( insect, shellac ) , oils, gums, waxes, and proteins . Figure
5 . 1 2 gives examples of spectra for these categories. More information on
vibrational group assignments for these natural materials may be found
elsewhere ( Bellamy 1 9 80; Omecinsky and Carriveau 1 9 8 2 ) .
Classification o f spectra for these general classes o f natural
organic materials can be simplified based on the position, intensity, and
shape of the carbonyl and hydrocarbon absorption bands. Figure 5 . 1 3
i s a flowchart that separates each material based on the presence or
absence of characteristic bands. The schematic trail is followed until
one of the final blocks is reached.
Positive identification of a material should always be made by
final, direct visual comparison of the unknown spectrum to reference
spectra. However, there are only a few good reference spectral collec
tions, books, and digitized spectra available for natural products.
Appendix I lists some of these ( see Infrared Users' Group 1 995; Hummel
and Scholl 1 9 8 1 ; and Snodgrass and Price 1 9 9 3 ) .
Waxes
Waxes are long-chain hydrocarbon materials that can be produced by
either plants or animals. Waxes are very stable, not changing significantly
as they age (Mills and White 1 994 ) . Kuhn provided a basis for the
identification of waxes in works of art using IR spectroscopy ( Kuhn
1 9 6 0 ) . More recently, Besaninou presented a thorough history of waxes
and their methods of analysis ( Besaninou 1 9 8 4 ) . Parra and Serrano used
1 01
Spectral Interpretation
Wax
(beeswax)
Oil
(linseed oil)
Resin
(mastic)
Q)
<.)
c
te.=*-'"'"
E
(f)
c
Resin
(shellac)
Protein
(hide glue)
Gum
(gum arabic)
Figure 5 . 1 2
I R transm ittance spectra for several types
of u naged natural organic materials.
4000
3600
3200
2800
2400
2000
1 800
1 600
1 400
1 200
1 000
800
600
Wavenumber (cm- ' )
IR spectroscopy and other techniques to examine wax seals and their
attached textile remnants ( Parra and Serrano 1 99 0 ) . Other authors have
used IR spectroscopy to identify beeswax in Egyptian paints ( Birstein and
Tul' Chinskii 1 97 9 ) , on a column of a German church ( Bleck and Ziessler
1 96 7 ) , and in samples excavated in Sudan ( Delbourgo and Gay 1 9 6 8 ) .
I n a wax spectrum, the many CH2 groups (methylenes) i n the
chain produce the characteristic and predominant stretches at 2926 and
1 02
Chapter
5
Carbonyl band
( 1 630-1 750 cm-')
1 520-1560
1450
1 240
1 080
3300
C-H stretches
(2850-2960 cm-')
( 1 630-1 680 cm-' )
Protein
( 1 695-1 7 1 5 cm-' )
Tree resin
( 1 740-1 750 cm-')
2930-2958 (s)
2865-2875 (s)
1 448-1467
1 382-1387
2955-2957
3400 (s)
291 8-2920 (s)
1 6 1 6-1 645
1 235-1 250
2920-2934 (s)
2926-2928 (s)
1 1 78-1 1 84
2855-2860 (s)
2855-2557 (s)
2949-2851 (s)
1423- 1 440
1 078-1092
1 636
1 46 1 -1 464
(1 736-1 742)*
1 385
1 028-1038
1 466
1 238-1 244
1 472-1 475
1 220-1 240
887-897
1 4 1 0-1 416
1 1 59-1 1 67
1 464-1466
1 068-1 1 00 (s)
1 377-1 381
1 097-1099
( 1 1 7 1-1 1 84)'
1 250- 1 254
721-727
729-731
71 9-721
1 1 61-1 1 76
1 1 1 2-1 1 1 3
945
928-932
Figure 5 . 1 3
2 8 5 0 cm-I ( see Figs. 5 . 6 and 5 . 1 2 for paraffin and beeswax, respec
A flowchart to aid in characterization of
tively) . Confirmatory bands for waxes are small, sharp doublets at
several classes of natural organic materials
*
based on their IR absorption band posi
tions and intensities (s
= =
strong;
sent only i n ester-containing waxes).
pre
1 466/1462 cm- I and 730/720 cm- I . The splitting of the bands near
730 cm- I into a doublet indicates that there are at least four methylene
groups in the chain. The appearance of the doublets indicates the semi
crystalline structure of the wax ( Ludwig 1 96 5 ) . Any pure, long-chain
hydrocarbon will have CH2 chains with CH3 methyl end groups and pre
sent a spectrum similar to paraffin wax. Most natural waxes also contain
esters of higher fatty acids with fatty alcohols. Beeswax is composed of
about 70% higher aliphatic esters, with 1 3 % free wax acids and only
c=o
about 12 % hydrocarbons ( Fig. 5 . 1 2 ) . The ester groups account for the
weak
stretching band at 1 740 cm-I and for the C-O bands in the
1 1 75 cm-I region.
Oils
Oils, vegetable and animal, consist of glycerol esters of higher fatty acids
with even carbon numbers; their diversity lies in the type and composi
tion of the fatty acids (Mills and White 1 99 4 ) . Oils and fats are ubiqui
tous and have been used in many contexts; in art objects they are
commonly found as binding media in paintings and as residues in archae
ological samples. While chromatographic procedures are required for the
specific differentiation of the fatty acid components in oils, IR can readily
identify this class of materials ( Shreve et al. 1 950; Barclay 1 9 8 9; Kosek
and Green 1 992 ) . In addition, IR spectroscopy has been successfully used
to study the drying of linseed oil ( Baer and Indictor 1 976) and its changes
1 03
Spectral I n terpretation
with UV radiation ( Low and Baer 1 977), as well as its aging characteris
tics when mixed with pigments ( Meilunas, Bentsen, and Steinberg 1 9 90 ) .
Hedley and coworkers used I R spectroscopy t o evaluate changes i n the
dried oil film after cleaning treatments (Hedley et al. 1 9 9 0 ) .
Shown i n Figure 5 . 1 2 is a n example o f a typical oil spectrum
illustrating the significant CH2 stretches. However, due to the polar mol
ecular environment, the methylene bands, at 2926 and 2 8 5 5 cm- I , are at
slightly higher wavenumbers than those of the waxes. In addition, there
is a weak-to-medium olefinic C = C-H stretching band that occurs at
3020 cm- t • The intensity of this band depends on the state of dryness of
the oil, and in well-dried oils, this band will be very small. Oil spectra
contain a strong, sharp carbonyl band at 1 75 0- 1 740 cm- I , because of
the ester group. It is the only natural organic material of these five
classes that has an intense carbonyl band in this region. This is a clear
characteristic of oil. However, in mixtures with some pigments, the
carbonyl band may be shifted to slightly lower wavenumbers. Other
c-o c - o
bands characteristic of the oils are aliphatic C-H bands at 1 464, 1 3 79,
and 725 cm-t and the
three
bands at 1 240, 1 1 65 , and 1 1 03 cm- t • The
bands occur in a characteristic maple leaf pattern, for which
the band at 1 1 65 cm- t is the strongest.
Resins (tree)
Natural tree resins are primarily composed of aliphatic three-ring struc
tures called resin acids. The softer resins, mastic and balsam, have been
used as adhesives and varnishes, and the harder resins, such as copal and
amber, have been used for decorative beads and sculpture. Tree resins fall
into three main categories: ( 1 ) aromatic (e.g., benzoin, styrax ) , (2) diter
penoid (e.g., balsam, copal), and ( 3 ) triterpenoid (e.g., dammar, mastic)
(Mills and White 1 977). These resins vary in their degree of stability, and
some are susceptible to oxidation ( Mills and White 1 994).
Gianno and coworkers used IR to analyze over one hundred
southeast Asian natural resins and gums; those references served as a
base to identify coatings and adhesives found on ethnographic objects
( Gianno et al. 1 9 8 7 ) . Mastic and dammar resins, commonly used as
painting varnishes, have been spectrally characterized by Feller ( 1 954,
1 95 9 ) . IR spectroscopy was one method used by Burnstock and Learner
( 1 992) to monitor changes in mastic varnishes after they were cleaned
with alkaline reagents. IR spectroscopy was also used to study historic
varnishes (Korte and Staat 1 9 89; McCormick-Goodhart 1 9 8 9 ) , coatings
on African ceramics (Hexter and Hopwood 1 99 2 ) , and archaeological
residues ( Shearer 1 9 8 7) . Derrick ( 1 9 8 9 ) provided a schematic to differen
tiate five un aged resins found in furniture finishes using IR absorption
band positions.
Tar and pitches have been used since early times as putties,
paints, and waterproofing agents. Hadzi and Cvek ( 1 97 8 ) used IR to iden
tify "grave resins" found on urns in excavated graves as birch bark pitch.
First analyzed with JR, then confirmed with chromatographic methods,
pine pitches were found on an Etruscan shipwreck ( Robinson et al. 1 9 8 7)
and in Mediterranean transport amphoras (Beck, Smart, and Ossenkop
1 04
Chapter
5
1 9 8 9 ) . Asphalts and bituminous resins used as brown colorants in paint
media have been characterized with IR by Wolbers ( 1 9 8 4 ) .
Early I R studies showed that various sources of amber, a
fossilized resin, could be differentiated by their IR spectra ( Schwochau,
Haevernick, and Ankner 1 96 3 ; Beck, Wilbur, and Meret 1 964; Beck et al.
1 965; Langenheim and Beck 1 9 6 5 ) . Reference sets of amber spectra were
collected (Langenheim and Beck 1 9 6 8 ) and later used to identify amber
sources in Greek artifacts (Beck et al. 1 9 7 1 ) , in imported archaeological
artifacts (Beck 1 972 ) , in Etruscan j ewelry (Follette 1 9 8 5 ) , in samples
from Japanese tombs ( Fuj inaga, Takenaka, and Muroga 1 976), and in
objects from other archaeological sites (Todd et al. 1 976; Beck et al.
1 9 7 8 ) . Williams, Waddington, and Fenn ( 1 990) used IR spectroscopy to
examine the changes in amber after exposure to air pollutants. Grimaldi
noted that the routine use of IR spectroscopy for the characterization of
amber has significantly helped curators with the classification of artifacts
( Grimaldi 1 99 3 ) .
Oriental lacquer, o r urushi, is another significant plant resin
used in art objects that has been well studied by IR spectroscopy
( Masschelein-Kleiner and Heylen 1 96 8 ; Fujinaga, Takenaka, and Muroga
1 9 76; Kenjo 1 97 8 ; Carriveau 1 9 8 4 ) . Kenjo used IR to study the effects
of pH on the hardening of lacquer films (Kenj o 1 976 ) . More recently,
Derrick and coworkers showed that IR spectroscopy can be used to
distinguish between lacquer on Japanese furniture and the natural
resin-based imitation coatings developed in Europe in the eighteenth
century (Derrick, Druzik, and Preusser 1 9 8 8 ) .
The various types o f natural resins exhibit several important
spectral features. The cyclic ring structure of tree resin (mastic) gives a
spectrum with strong C-H stretching vibrations at even higher wave
numbers than those in the oils ( Fig. 5 . 1 2 ) . These are generally found at
295 8-2930 and 2 8 75-2 8 6 5 cm- I . Because there is a variety of molecular
environments for the methylene groups within the compounds in any
given resin and because there are several methyl (CH3 ) end groups, the
C-H stretches are not as sharp and as well separated as those previously
seen in the waxes and oils. Resins may be distinguished from the other
groups by two bands. The first band, which is usually weak and broad,
occurs at 2700-2500 cm-I and is due to the O-H vibrations of a dimer
ized carboxyl group. The second distinguishing band that all tree resins
contain is a strong carbonyl ( C = O ) stretch at 1 7 1 5- 1 6 9 5 cm- I . This
band broadens with resin degradation and oxidation, but the band maxi
mum remains within this wavenumber region ( see, for example, spectra
of light-aged mastic in Fig. 5 . 1 4 ) .
Bands i n the fingerprint region are characteristic for each
particular tree resin and may be used to distinguish among them. Figure
5 . 1 5 shows exemplary IR absorbance spectra for five commonly used,
unaged natural resins in furniture finishes. Figure 5 . 1 6 is an IR absorp
tion band identification key for these resins; included are family names
and major components (Derrick 1 9 8 9 ) . Once a natural material has
been classified as a natural resin by use of the information in the nat
ural products identification flowchart ( Fig. 5 . 1 3 ) , then the type of resin
105
Spectral Interpretation
Mastic
2.0
Q)
.D«()'"0if)
c
1 .0
0.2 +- ----------------�--------------------------�--�
�
900.0
1 000.0
1 800.0
1 500.0
Wavenumber (cm- 1 )
2.0
Sandarac
Q)
.D«()'"0if)
c
1 .0
Figure 5 . 1 4
I R absorbance spectra (1 800-900 cm-1 )
for th ree sets of fresh and deteriorated
�:d
natu ral resins (mastic, sandarac, and shellac). Each plot is a spectral overlay of
0.2
1 800.0
samples that were exposed to 0 , 37, 75,
1 500.0
1 000.0
900.0
1 000.0
900.0
Wavenumber (cm-1 )
and 1 5 1 kilojoules of en ergy from a xenon
arc lamp i n a temperature- and humidityShellac
controlled environment. At the longest
exposure time, all samples exh i bited d iscoloration and cracking. Note that the
absorption band position maxima remain
stable, w h i le the band shapes and relative
intensities change. The most significant
.D«()c'"0if)
Q)
0.5
changes are seen in the shapes and relative intensities of the carbonyl bands for
\,,"�"""'--",
mastic and shellac; for each of these carbonyl bands, the shortest band corresponds to the fresh resin sample, and the
tallest band corresponds to the most dete-
0.0
1 800.0
1 500.0
Wavenumber (cm- l )
riorated resin sample.
may be distinguished with the aid of the additional information pro
vided in Figure 5 . 1 6 .
This schematic provides a simplified structure for the easy
identification of the presence of a resin in a spectrum by a list of its
1 06
Chapter
5
Rosin
Copal
Mastic
Shellac
Figure 5 . 1 5
Exemplary I R transm ittance spectra for five
types of unaged natural resins.
4000 3600
3200
2800
2400
2000
1 800
1 600
1 400
1 200
1 000
800
600
Wavenumber (cm- 1 )
absorption band positions. The strongest bands in the resin spectra are
generally the carbonyl and hydrocarbon stretching frequencies. These
bands, listed at the top of the key, can provide a distinction for four of
the resins. Sandarac and copal are chemically and spectrally very similar
and may be distinguished only by some smaller bands in the fingerprint
region (2000-500 cm- 1 ) . The presence of at least half of the listed bands
1 07
Spectral Interpretation
Source= Tree
/
Carbonyl bands
C-H stretches
Vinyl stretches
and bends
Characteristic
fingerprint
region bands
Figure 5.1 6
A flowch art to aid in characterization of
Resin
five types of natural resins based on their
I R absorption band positions (absorption
FamilyA,B
bands are represented as wavenumbers
[:t2 . 4 cm-1 ] ; A
= =
Mills 1 977; B
Mattiello
1 941 ) . (For more i nformation, see Derrick
1 989 .)
Major
componentsA, B
:......"
Source=lnsect
;7
�
1
7
5
1
7
2
1
6
9
0
1
7
0
1
7
001
7
5
3
0
3
8
L"'"
22646-98372-06654 22984739 29847 2983570
1166I927 311406I67943 14518-65-10460 116436
1143296375591 /125193-21952'""63 111026455861 1 61132-579102176
19381007 1142395637 18254098 85307 1190465421
86720532 980527632 79 7320
7
8
9
7
9
2
rPinoascine Cusparensdaarccea Arauccoaprialcea Anacmardstiaiccea Lsaecsrihefetlradlcabcya
abietcadsien pscimonamdr dauinceiondcpaimaccidirdss scaonmdarucniodcpaimcaidrsic comftprilexrpmeinxtusre lashceoliclactoidnse
'"
7
I
I
in an unknown sample spectrum is a strong indication that a particular
resin is present. Final confirmation comes through visual comparison of
the sample spectrum with a reference spectrum of a known material.
Resins (insect)
Shellac is a resin excretion from the lac beetle. Chemically, shellac resin
is a complicated mixture of lactones, esters, and ethers of aliphatic and
aromatic polyhydroxy acids. The C-H stretching bands ( Figs. 5 . 1 2 , 5 . 1 5 )
fall i n positions similar t o those o f oils, at 2934-2920 and at 2 8 5 7 em- I .
The carbonyl band in fresh shellac i s a characteristic doublet from the
c-o
ester ( 1 735 em- I ) and from the acid ( 1 7 1 5 em- I ) . A small olefinic band
occurs at 1 6 35 em- I . Several
bands are present, most noticeably at
1 240, 1 1 63 , and 1 040 em- I ; they are due to the ester, acid, and alcohol
groups. A double band at 73 01720 cm-I ( from partially crystalline long
chain hydrocarbons) occurs in many shellacs and is probably due to
accompanying shellac wax. Shellac is included in the resin identification
schematic presented in Figure 5 . 1 6 .
1 08
Chapter
5
Proteins
Proteins are polymeric substances composed of amino acid monomeric
units . The proteins present in living organisms consist of various com
binations and proportions of twenty naturally occurring amino acids.
Proteinaceous materials used in art objects may be from animal tissues
(parchment, leather, hair, ivory) or from their by-products (glue, egg,
casein, albumin, blood ) . All types of proteins, as a general material class,
are readily identifiable by their IR spectra ( Perron 1 9 8 9 ) . Close examina
tion of absorption band position and intensities can show the denatura
tion of collagen to gelatin (Birstein and Tul'Chinskii 1 9 8 1 ; Payne and
Veis 1 9 8 8 ; Derrick 1 9 9 1 ) . FT-IR analysis has also been used to differenti
ate between modern elephant ivory and ivory from other sources, such as
walrus, hippopotamus, or ancient mastodon ( Lee 1 9 9 1 ) .
Protein spectra form a consistent recognizable pattern of
absorption peaks ( Fig. 5 . 1 2 ) . Proteins are characterized by the presence of
amide I and amide II bands near 1 650 and 1 5 5 0 cm- I , respectively. These
two bands along with another, occasionally referred to as an amide III,
found near 1 450 cm- I , form a consistent stair-step pattern. Additionally,
the presence of an amide may be confirmed by the N-H stretching band
near 3350 cm- 1 . While IR is very useful for identifying the presence of a
protein, few spectral differences are seen between various protein types,
including materials as different in amino acid composition as fish glue
and albumin. Thus, a secondary method, such as liquid or gas chromato
graphy, must be used to determine the exact amino acid composition.
Gums
Carbohydrates are natural polysaccharides composed of various propor
tions of several monosaccharide units. They are typically water soluble.
Some common examples are sugar, starch, cellulose, and plant gums. An
excellent review of plant gums and their use as art materials was given by
Twilley ( 1 98 4 ) . Birstein used IR spectroscopy to identify natural gums as
binders in central Asian wall paintings ( 1 975 ) and as protective coatings
in late antique and early-middle-age Egyptian tombs (Birstein and
Tul'Chinskii 1 9 77). Masschelein-Kleiner and Tricot-Marckx detail method
ology for the IR analysis of gums and illustrate spectra obtained neat and
after acid hydrolysis (Masschelein-Kleiner and Tricot-Marckx 1 96 5 ) .
Gums a n d cellulose are long-chain polymers o f sugars (poly
saccharides). Sugars have a high proportion of O-H groups bound to the
carbons. This structure produces a very characteristic IR pattern for the
c-o
polysaccharides ( Fig. 5 . 1 2 ) , which have two strong, broad bands: one at
about 1 0 8 0 cm-1 due to
and the other at about 3 3 00 cm- 1 due to
the O-H groups. These bands are typically about equal in intensity. The
C-H stretches tend to be weak and poorly resolved. All polysaccharides
also contain a moderately strong band at 1 620 cm- 1 that is partially
associated with intramolecularly bound water and partially due to the
presence of a carboxyl group. Some gums, such as gum tragacanth, also
contain a weak-to-moderate band at 1 73 5 cm- I , which is associated with
an ester-containing component.
Spectral I nterpretation
1 09
Synthetic resins (polymers)
Over forty years ago, many industrial labs purchased IR spectrometers
for the analysis of rubbers. As applications for other polymers grew, so
did the breadth of samples analyzed by IR. Unlike natural materials,
which are complex mixtures of many components, synthetic resins
tend to be pure, specific molecular structures that provide sharp, well
defined IR absorptions. These very specific, recognizable IR patterns
make IR spectroscopy the method of choice for the identification
of polymers.
IR analysis has been used successfully to analyze polymers in
objects of art and in art conservation practice ( Freeman 1 979; Martin
1 9 8 8 ; Pratt 1 9 9 1 ; Shearer and Doyal 1 9 9 1 ) . The capabilities and limita
tions of IR were examined for analyzing acrylic ( Stringari and Pratt
1 99 3 ) and alkyd (Hodson and Lander 1 9 8 7) paint media. In poly(vinyl
acetate) films prepared with different solvents, IR spectroscopy showed
conformational variations in the polymer ( Hansen et aI. 1 9 9 1 ) .
Figure 5 . 1 7 shows spectra o f several important polymers
selected as synthetic equivalents to the natural products shown in
Figure 5 . 1 2 . Polyethylene is a long-chain hydrocarbon, similar to nat
ural waxes such as paraffin. Many types of polyester resins, such as
alkyds and acrylics, are used as modern artist materials and as conser
vation materials. Some polycyclohexanones, such as MS2A and Laropol
K-80, have been proposed as substitutes for natural resin varnishes.
Nylon, a synthetic polyamide, is a chemically resistant material used in
fabrics and liners. The spectrum of a water-soluble, modified cellulose,
Klucel F, is also shown. More information on vibrational group assign
ments for many synthetic resins may be found in these Appendix I
references: Bellamy 1 9 75; Kagarise and Weinberger 1 9 54; Stimler and
Kagarise 1 9 6 6 ; Zeller and Pattacini 1 9 73 ; Chicago Society for Coating
Technology 1 9 8 0 .
Flowchart for synthetic resins
An identification flowchart for classes of synthetic materials is pre
sented in Figure 5 . 1 8 . It is similar in design and use to the chart pre
sented for natural materials. This schematic method aids in identifying
the type or class of material present. The presence of plasticizers and
fillers can complicate the identification of the base polymer. However,
since the spectrum is the sum of its components, it is usually possible
to find sufficient unobscured bands to characterize the main polymeric
component.
Positive identification of a material should always be made by
final, visual comparison of the unknown spectrum to those in reference
spectral collections. Several good reference spectral collections, books,
and digitized spectra-such as Sadder Research Laboratories, Hummel
and Scholl ( 1 9 8 1 ) , and Chicago Society for Coating Technology ( 1 9 8 0)
are available for polymers and additives ( see Appendix I). The Gettens
Collection contains reference spectra for several early polymers from the
1 930s and 1 940s (Appendix I, Snodgrass and Price 1 9 9 3 ) .
110
Chapter
5
Polyethylene
(bubble wrap)
OJ
o
c
te�?f!.'"'"
E
(/)
c
Polycyclohexanone
(Laropol K-80)
Polyamide
(nylon- 1 1 )
Cellulosic
(Klucel F)
Figure 5 . 1 7
Exemplary I R transmittance spectra for five
classes of u naged synthetic materials.
4000
3600
3200
2800
2400
2000
1 800
1 600
1 400
1 200
1 000
800
600
Wavenumber (cm-1)
Characterization process for polymers
Polymers are usually composed of long chains of two or three primary
functional groups. The following discussion uses the wavelength regions,
mentioned earlier in this chapter, to classify several types of synthetic
polymers based on the presence and absence of major functional groups
in their IR spectra. All regions of the spectra should be examined and
cross-checked. The goal of functional group analysis is to focus on one
or more classes of materials for in-depth visual comparison.
111
Spectral Interpretation
weak
or absent
strong
weak
or absent
Aliphatic
hydrocarbons
Figure 5.1 8
A flowchart for the ch aracterization of
ethers
several classes of synthetic polymers based
on their I R absorption band positions and
intensities.
OH-NH region (4000-2600
em- i ) .
The absence of broad
envelope O-H and N-H bands in this spectral region indicates that the
sample does not contain amines, amides, alcohols, or organic acids. This
rules out materials such as polyamide (e.g., nylon), phenolic resins (e.g.,
Bakelite ) , polyurethanes, polyethylene glycols (e.g., PEG- I OO ) , and
polyvinyl alcohols (e.g., Elvanol ) , as well as some cellulose esters,
alkyds, and epoxies. Note, however, that if the sample was prepared
using a hygroscopic alkali salt, such as KBr, the presence of an O-H
band in this region may derive from absorbed water rather than from
the sample structure.
Hydrocarbon stretching region ( 3 2 00-2800
em-i ) .
Absorption bands between 3 1 00 and 3000 cm- i correspond to an aro
matic or vinyl C-H group and may indicate compounds such as poly
styrene, phenolic resins, some polyurethanes, epoxies, or phthalate
plasticizers. A sharp band at 2 9 8 0 cm- may indicate silicone resin or oil.
i
Strong sharp, methylene absorption bands (2925 and 2 8 5 0
cm - t ) with no carbonyl band ( see next section) indicate the presence o f a
long-chain hydrocarbon polymer, such as polyethylene, polypropylene,
butadiene, or natural rubber. The spectra for some polyethylenes are only
slightly different from the spectra for paraffin waxes.
Numerous aliphatic esters, such as polyesters, have moderate
to strong methyl and methylene stretching bands. However, if the spec
trum has weak or absent C-H vibrations, then compounds such as fluoro
carbons (e.g., Teflon), polyimides (e.g., Kapton), poly(vinyl acetates)
(e.g., AYAA ) , epoxies (e.g., Epon), or regenerated celluloses (e.g., cello
phane, rayon) should be examined.
Window region (2800-1 800
em - i ) .
This region is associated
with adjacent double and triple bonds. In polymers, compounds containing
isocyanate or nitrile groups will absorb in this region about 2 1 00 cm- t .
Examples o f nitrile-containing polymers are acrylonitrile-butadiene-styrene
112
Chapter
5
(ABS rubber), acrylonitriles (e.g., Orlon, Saran F-120), and some poly
urethanes (e.g., Adiprene L- 1 00).
Overtone and combination vibrations for a monosubstituted
aromatic will occur as small, regularly spaced bands from 1 950 to
1 650 em- I . These bands, when seen in the spectrum for a polymer, may
indicate that polystyrene or phenolic resin is a sample component.
Carbon double bond region ( 1 800- 1 5 00 em- I ) . Because the
carbonyl band ( 1 850-1 650 em- I ) is one of the most important and usu
ally one of the strongest, this region is sometimes the first examined.
While it can be difficult to assign an exact type of carbonyl (i.e., ester,
aldehyde, ketone, etc . ) in every case, the presence or absence of any car
bonyl band is a key feature of a spectrum.
Polymers with a strong carbonyl band in the region of
1 750- 1 700 cm- I are polyesters (e.g., Mylar), acrylics (e.g., Acryloid),
alkyds (e.g., Glyptal), poly( vinyl acetates) (e.g., AYAA ) , plasticized
polyvinyl chlorides (e.g., vinyl storage sleeves), polyurethanes (e.g.,
Adiprene L- 1 00 ) , and cellulose esters (e.g., cellulose acetate) . A carbonyl
band shifted down to about 1 650 cm- I may indicate that polyamines
(e.g., Melmac), polyamides (e.g., nylon), or cellulose nitrates (e.g., Duco,
collodion) are present.
Examples of polymer classes that have weak or absent car
bonyl bands in the region of 1 750-1 650 cm-I are polyolefins (e.g., poly
ethylene, polypropylene, etc . ) , polystyrenes (e.g., Styrofoam, Fom-cor),
fluorocarbons (e.g., Teflon), phenolic resins (e.g., Bakelite ) , unplasticized
polyvinyl chlorides (e.g., Geon ) , polyvinyl alcohols (e.g., Elvanol) , acry
lonitriles (e.g., Orlon, Saran F-120), regenerated celluloses (e.g., cello
phane, rayon), cellulose ethers (e.g., methyl cellulose, Ethylcel ) , silicone
resins, and some epoxies (e.g., Araldite ) .
Epoxies that are a mixture o f epichlorohydrin and Bisphenol
A consistently produce spectra with a strong absorption band near
1 5 1 0 cm-I and a weaker but sharp band at 1 6 1 0 em- I . Esterified epoxies
and plasticized epoxies will show a carbonyl band near 1 720 em- I .
Phthalates are plasticizers that produce a strong carbonyl
band at 1 735 cm-I and small but distinct doublet bands at
1 600-1 5 8 5 em- I . They are often combined with cellulose nitrates,
polyvinyl chlorides, alkyd resins, or polyesters. Organic acids and acid
salts, such as stearates, are also common additives. They usually have
one or two sharp absorption bands near 1 5 8 5-1545 em- I .
Absorbed water, i n the sample or i n a n accompanying
alkali halide salt plate, will produce a weak, broad absorption band
near 1 65 0 em- I .
Fingerprint region ( 1 5 00-5 00 em- I ) . The fingerprint region is
most useful when the sample spectrum is directly compared to reference
spectra. When two spectra are overlaid, any missing or absent bands in
either spectrum show that the compositions of the two materials are dif
ferent, even if the functional group bands are the same.
A strong, broad absorption in the range of 1 1 00-1 000 em-I
may indicate regenerated celluloses (e.g., cellophane, rayon), cellulose
ethers (e.g., methyl cellulose, Ethylcel ) , silicone resins, or inorganic addi-
Spectral Interpretation
113
tives. Silicone resins have very characteristic sharp bands at 1 260 and
800 cm- I , one on each side of the broad band.
Aromatic compounds have sharp, strong bands i n the region
of 1 000-650 cm- i . The presence of sharp bands in this region may indi
cate compounds such as polystyrene, epoxies, phenolic resins, some
polyurethanes, or phthalate plasticizers.
Colorants
Minerals, clays, and other inorganic materials are commonly used as
colorants and fillers in paints . Many of these materials may be readily
identified by IR spectroscopy as well as by several analytical methods,
such as scanning electron microscopy with energy dispersive spec
troscopy, X-ray diffraction, X-ray fluorescence, and polarized light
microscopy. These other methods, which generally provide elemental
analysis or crystal structure, are complementary to the molecular species
information obtained from IR. An advantage for IR is that it supplies
information on both the organic and inorganic components in a paint.
An excellent source for reference spectra on artists' colorants
is the Artists' Pigments handbook series, volumes 1, 2, and 3, which pro
vide in-depth chapters on the characterization of numerous specific pig
ments, each of which provides corresponding IR spectra ( Feller 1 9 8 6 ; Roy
1 993; West-FitzHugh 1 997). Additionally, a review article by Newman on
IR spectroscopy for the analysis of painting materials provides interesting
applications and comparative spectra, as well as an extensive bibliography
( Newman 1 9 8 0 ) . He cites several articles on the IR spectral identification
of pigments, including Riederer 1 969; Kuhn 1 9 70; Gettens, West
FitzHugh, and Feller 1 974; Gettens and West-FitzHugh 1 9 74; Riederer
1 974; and Siesmayer et al. 1 975 . More-recent articles use IR as one
method to identify pigments in paints ( Lear 1 9 8 1 ; Guineau 1 9 8 3 ), in
grounds ( Schulz and Kropp 1 9 9 3 ) , and in inks on medieval manuscripts
( Orna et al. 1 9 8 9 ) . IR spectroscopy was also used in the following tech
nological studies of pigment and paint sets: Winslow Homer's watercolor box was analyzed by Newman, Weston, and Farrell ( 1 9 8 0 ) ; the
Hafkenscheid collection of 1 3 9 pigments and painting materials dating
from the early nineteenth century was analyzed by Pey ( 1 9 8 7 ) ; and a col
lection of pigments used in a 1 929 diorama at the Missiemuseum at Steyl
Tegelen was analyzed by de Keijzer and Karreman ( 1 9 8 9 ) .
I R spectroscopy i s also useful i n the identification o f organic
colorants and dyes, particularly when they occur as pure materials. For
example, phthalocyanine blues and greens produce very distinctive sharp
bands from 1 700 to 700 cm- i (Newman 1 9 8 0 ) . Other studies also used
IR to identify synthetic organic pigments ( Venkataraman 1 977; Strauss
1 9 84; Gillard et al. 1 994 ) . When organic colorants or dyes have been
mordanted on a fiber or particle, IR analysis of the combined material
produces a strong spectrum for the fiber or particle overlaid on the col
orant absorption bands. This hinders the colorant's identification by IR
spectroscopy, particularly if it is present in low concentrations (Kirby
and White 1 99 6 ) . McGovern and Michel ( 1 990) used IR, as one of
several techniques, for the confirmation of royal purple dye in an
114
Chapter
5
archaeological vessel. Low and Baer ( 1 97 8 ) studied alizarin complexes
prepared on an alumina lake. Colorants in fragile historic and prehistoric
colored fabrics were characterized by IR micro spectroscopy (Martoglio et
al. 1 9 90; Jakes, Katon, and Martoglio 1 99 0 ) . Martoglio and coworkers
also showed that IR characterization of colorants can be assisted by the
use of UV/Vis micro spectroscopy on in situ material (Martoglio et al.
1 99 0 ) . Another analytical method for the identification of colorants is
first to extract the colorant from the substrate with acid or base and then
to use IR, UVNis, or thin-layer chromatography for characterization
( Schweppe 1 9 79, Schweppe 1 9 8 9 ; Saltzman, Keay, and Christensen 1 96 3 ;
Saltzman 1 992; Hansen, Wallert, a n d Derrick 1 99 5 ) . Typically, chro
matographic analysis methods are preferred for the analysis of dyes.
McClure, Thomson, and Tannahill ( 1 96 8 ) provide ninety-six reference
IR spectra for organic colorants. Digitized spectral collections of organic
dyes and colorants are distributed by Bio-Rad Sadder and Aldrich
Nicolet ( Appendix I ) . See the above references for more information on
the identification of dyes, as further details are not given in this text.
Characterization process for pigments
Six exemplary IR spectra for inorganic materials used as pigments or
fillers are shown in Figure 5 . 1 9 . In general, absorption bands for inor
ganic materials are broader, are fewer in number, and occur at lower
wave numbers than absorption bands for organic materials. This is due to
their external ion structure (i.e., solid, sometimes crystalline matrix), as
well as to their internal ion composition (i.e., functional groups) . This
section will examine the basic characterization of absorption bands for
inorganic materials. Additional information on vibrational group assign
ments of minerals and inorganic materials may be found in the following
references ( see Appendix I ) : Farmer 1 9 74; Bellamy 1 975; Gadsen 1 9 75;
Zeller and Juszli 1 975.
External i o n structure. Pigments, minerals, and clays used in
works of art are solids at room temperature. With the exception of
amorphous silica, the repeating set of molecular units (-A-B-A-B-A-B-)
exists as a semirigid matrix in a layered, or three-dimensional, crystalline
structure called a lattice. The lattice structure restricts many molecular
transitions: translational, rotational, and even some vibrational motions.
In some cases, each functional group (A, for example) may not have an
environment identical, or equivalent, to other A functional groups.
Depending on their position in the overall pattern of molecules, some A
functional groups may freely vibrate, while other A functional groups
may have vibrational motion limited by space or direction. This situation
could result in a split, or degenerate, vibrational band that appears as
two or more adj acent bands. Alternatively, the restricted motion can
broaden absorption bands.
Vibrational transitions of the lattice structure, or lattice vibra
tions, usually occur at low wavenumbers in the far-IR region. Thus, this
region is particularly useful for detailed studies of a mineral's structure.
Internal ion composition. A simple inorganic compound, such
as table salt ( sodium chloride, NaCI ) , has one cation, sodium (Na + ) , and
115
Spectral Interpretation
Chalk (calcite)
(CaC03)
Malachite
(CuC03· Cu[OHb)
Barite
(BaS04)
Plaster
(2CaS04· H20)
Silica
(amorphous Si02)
Clay
(kaolin)
Figure 5 . 1 9
Exemplary I R transmittance spectra for six
inorganic pigments and fillers.
4000
3600
3200
2800
2400
2000
1 800
1 600
1 400
1 200
1 000
800
600
Wavenumber (em-')
one anion, chloride ( Cl - ) , and thus, it can be classified as a simple
anionic compound. Most simple anionic compounds will not produce
any vibrations in the mid-IR range, and their lattice vibrations occur in
the far-IR region. Because of this lack of absorption bands in the mid-IR
region, many materials with simple anions (e.g., NaCl, KBr, zinc selenide
[ZnSe] , silver chloride [AgCl] , etc . ) are used as IR transparent windows.
A more complex inorganic compound, such as chalk ( calcium
2
carbonate, calcite, CaC0 3 ) , has calcium ( Ca + ) as the cation and carbon-
116
Chapter
5)
ate ( C0 3 = as the anion. Carbonate can be classified as a complex anion,
because the anion is itself a functional group. The covalent bonds in the
carbonate tightly hold the anion together. Molecular vibrations within the
anion functional group are termed internal vibrations. Complex anions
produce characteristic absorption bands that are very useful for charac
terizing inorganics (Table 5 . 3 ) . The attached cation, whether it is calcium,
magnesium, or lead, will have only a slight effect on the position of the
absorption bands for the complex anion. In general, heavier cations will
shift the band to a lower frequency (Nyquist 1 96 8 ) . The effect is most
prominent in the lower-wavenumber bending vibrations.
Water of hydration. Water adsorbed on the surface of a
sample or incorporated in an amorphous structure will produce broad
O-H stretches ( 3400 and 1 65 0 cm- l ) , such as were noted in organic
compounds. Water molecules incorporated in the lattice structure of a
crystalline molecule, however, will produce specific, sharp, characteristic
absorption bands in the regions of 3 8 00-3200 and 1 700-1 600 cm- l .
The environmental symmetry seen by each hydroxyl group determines
whether the band is single or split. The unique patterns of the hydroxyl
absorption bands near 3 8 00-3200 cm- l are very important for character
izing the composition of hydrated inorganics.
Hydrated layered silicates (e.g., kaolinite, talc) resemble a
double-deck sandwich with the water molecules positioned in sheets
between the silicate anions and interlayer cations. This lattice confor
mation restricts the direction in which the O-H groups can vibrate.
Fortunately, fine distinct absorption bands are produced that are a sensi
tive indicator of the material. For example, O-H stretches for talc occur
as one sharp band at 3676 em-I, with a smaller band at 3660 cm- l . The
hydroxyl stretches for kaolinite show as two sharp bands at 3 700 and
3620 cm-l with two slightly smaller bands between 3 6 70 and 3652 cm-l
(Appendix I, Farmer 1 9 74 ) .
Carbonates. Carbonates, such as calcite ( CaC03), cerussite
c-o
( PbC03 ) , azurite ( 2CuC0 3 ·Cu(OH2 ) ) , or malachite ( CuC03 ·Cu(OH2 ) ) ,
show a t least one strong absorption band from
stretching i n the
l
region of 1 5 50- 1 3 5 0 cm- ( Fig. 5 . 1 9 ) . In anhydrous compounds, such as
calcite, the band is smooth, symmetrical, and broad. In hydrated carbon
ates, such as malachite, this absorption band is split.
Table 5.3
Vibrational frequencies for selected com
plex anionic groups.
Stretch (cm- 1 )
Anion
=
Water of hyd ration ( · H 2 0)
3800-3200
1 700-1 600
1 550-1 350
900-650
Nitrate ( N 0 3-)
1 500-1 250
850-700
Sulfate (SO
)4 )
)
Carbonate (C0 3
=
1 200-1 050
680-600
Phosphate (PO 4�)
1 300-900
600-550
Silicate (Si0 3
1 200-800
800-400
=
Formates, acetates, and oxalates
1 700-1 300
Cyanates, cyanides, and thiocyanates
2200-2000
1 050-700
117
Spectral I nterpretation
Carbonate bending vibrations produce sharp bands i n the
region of 900-650 cm- l . These bands show measurable frequency devia
tions corresponding to the attached cation. For example, the out-of-plane
bending vibration for calcium carbonate ( calcite) occurs at 8 72 cm- I ,
while the same vibration occurs a t 8 4 1 cm- l for cerussite ( lead carbon
ate ) and at 820 cm-l for malachite ( basic copper carbonate) (Newman
1 9 8 0 ) . Because few organic compounds have strong absorptions in this
region, these sharp bands are very useful for confirmation and
identification of carbonates in a spectrum.
Hydrated carbonates-hydrocerussite (PbC03 ·Pb ( OH 2 ) ) ,
azurite ( 2 CuC0 3 · C u ( OH2 ) ) , o r malachite ( CuC0 3 · Cu ( O H2 ) )-have
absorption bands due to hydration at 3 5 3 5 , 3425, and 3 40013 320
( split) cm-I, respectively ( Appendix I, Farmer 1 9 74 ) . Additionally,
small, sharp O-H bending vibrations occur at 1 1 00-1000 cm- l for the
hydrated carbonates.
Sulfates. Sulfates, such as gypsum ( CaS04 ·2H2 0 ) , anhydrite
( CaS04) , and barite ( BaS04), show a strong S-O stretching vibration
s - o s-o
band in the region of 1 200- 1 0 5 0 cm- l (Fig. 5 . 1 9 ) . This band is split i f
each o f the
bonds i n the tetrahedral sulfate anion sees a different
environment, as in the barite. Another small band occurs near 1 000
cm-l, because of an
bending vibration, along with sharp, slightly
stronger bands at 700-600 cm- l .
Changes i n the state of hydration make noticeable differences
in spectra. For example, plaster ( 2CaS04·H2 0 ) and gypsum
( CaS04·2H2 0) can be readily distinguished by the hydroxyl absorption
bands near 3 5 00 and 1 600 cm- l . Specifically, plaster has hydroxyl bands
at 3 6 1 5 , 3465, and 1 630 cm- I , while gypsum has bands at 3555 and
1 690 cm- l . Souza and Derrick used IR spectra to quantitatively deter
mine the proportions of plaster and gypsum in gesso sottile and gesso
grosso layers (Souza and Derrick 1 99 5 ) .
Silica and silicates. Amorphous silica produces a strong Si-O
stretching band near 1 0 5 0 cm- l that has a recognizable asymmetric
shape from a shoulder near 1 200 cm-l ( Fig 5 . 1 9 ) . Nearly all types o f
glass (including smalt) produce an absorption band that i s similar in
appearance, even though glass is composed of a wide range and mixture
of materials. The similar IR spectra occur because the basic glass struc
ture contains an Si-O backbone . Since IR spectroscopy cannot differenti
ate glass types, it is not the method of choice for characterizing glass
constituents. While the crystalline silica mineral quartz has the same pri
mary absorption band near 1 1 00 cm- I , it also has a unique, but small,
doublet band near 790 cm-l that is very characteristic.
Silicates have a fully ordered crystalline lattice structure. This
produces a well-defined Si-O absorption band at 1 200-800 cm- l . In lay
ered silicates, such as kaolin, the band is split into two or more peaks,
since some of the Si-O bonds are held perpendicular to the layers, while
other vibrate in-plane with the layers. In three-dimensional silicates, such
as ultramarine ( lazurite) , the Si-O absorption band is smoother, and split
ting, when it occurs, is less defined. Bending vibrations for Si-O usually
occur below 600 cm- l .
Chapter
118
5
The hydration absorption bands for layered silicates, men
tioned earlier, are uniquely distinctive. Because of restricted molecular
motion of the water molecules, these absorptions occur as sharp, well
defined bands in the region of 3 700 cm - 1 . Excellent reference spectra for
these silicate hydration absorption bands are provided in Farmer ( 1 9 74;
see Appendix I). These bands are useful for identifying silicate species,
even in instances where X-ray diffraction has failed.
In the production of ceramics, clay undergoes thermal trans
formations in its lattice structure. At 400-600 °C, clay dehydrates, losing
all water molecules. An IR spectrum collected on a clay heated to this
temperature will not have any hydroxyl absorptions. When clay is heated
to higher temperatures, 970 °C for kaolinite, the lattice structure col
lapses, producing an amorphous, glasslike material. Accordingly, its IR
spectrum will resemble glass, with a single broad absorption band at
1 200-800 cm- 1 .
Often the I R spectra for ochres o r earth pigments, found in
both ancient and modern paintings, correspond to spectra for silica and
silicates (Newman 1 9 9 6 ) . As the natural earth pigments were simply dug
out of the ground, they contain a mixture of minerals, including clay
and quartz. The clay and quartz are readily identified by their absorp
tion bands, while the compounds responsible for the pigment color
rarely have any absorption bands in the mid-IR range. The color of red
ochre is due to anhydrous iron oxide ( hematite ) ; that of yellow ochre is
due to hydrated iron oxides (most often goethite ) ; and brown earth pig
ments, such as umbers, contain manganese oxides. Of these colored
compounds, only the absorption bands near 8 5 0 cm-1 for goethite
appear in the mid-IR region.
Infrared spectral characterization of pigments
With a typical mid-IR FT-IR instrument, most inorganic compounds
that contain complex anions ( carbonates, sulfates, silicates, etc . ) can be
identified. Inorganic compounds that contain simple anions ( oxides,
sulfides, etc . ) often cannot be identified. Since many inorganic pigments
and fillers contain complex ions, they are amenable to identification by
mid-IR region analysis . Table 5 . 4 lists selected pigments with their for
mulas and mid-IR absorption band regions.
Identification of a spectrum should always be made by final,
direct comparison of the unknown spectrum to those in reference spectral
collections. However, with pigments and minerals, it is important to eval
Table 5.4 (opposite page)
Pigme nts and fillers correlated with I R
uate information known about the sample and reference, especially when
absorption band ranges. Most pigme nts
commercial pigments are used as references. Some commercial sources
with complex anions absorb in the mid- I R
may label pigments on the basis of their color rather than their composi
region. A l l pigments have absorption
tion. Additionally, many pigments sold in the nineteenth and twentieth
bands in the far- I R region (below
centuries are actually mixtures of different compounds, such as a colored
700 cm-' ) . The freq uency range is marked
compound with one or more fillers (Newman 1 99 6 ) . Since some compo
for pigments that are active in the
nents in a pigment mixture may have absorption bands in the mid-IR
mid - I R region. More than one band may
region while others do not, the IR spectrum of the mixture may not rep
= = =
occur within each region (s
m
med i u m ; w
weak).
strong;
resent the total composition of the material. For example, titanium diox
ide does not have any absorption bands in the mid-IR region, but a
119
Spectral I nterpretation
Mid-IR
bands?
Formula"
Pigment
White (with extenders)
Aluminum hyd rate
Anhydrite
Barium su lfate
Chalk (calcite)
Clay (kaolin ite)
Gypsum
Lithopone
yes
yes
yes
yes
yes
yes
yes
yes
yes
yes
no
yes
AI(OH)3
CaS04
BaS04
CaC0 3
AI203 0 2Si02 0 2 H2O
CaS04 02H2O
BaS04, ZnS
Si02
Si02
3 Mg004Si02 0 H P
Quartz
Silica (amorphous)
Talc
Titan ium dioxide
White lead
(basic carbonate)
Ti02
PbC0 3 0 Pb(OH)2
PbS04 0 pbO
yes
ZnO
no
CdS, CdSe
CdS, CdSe, BaS04
no
yes
PbOo PbCr04
AS2S2
Pb3 04
HgS
yes
no
no
no
Yellow
Barium yellow
Cadmium yellow
Chrome yellow
Massicot (litharge)
Lead tin yellow
Strontium yellow
BaCr04
CdS
PbC r04
PbO
Pb2Sn04
SrCr04
yes
no
yes
no
no
yes
Green
Chromium oxide
Chrysocolla
Cobalt green
Green earth
Malachite
Verd igris
Viridian
Cr2 0 3
CuSi0 3 0nH2O
CoO onZnO
K,AI, Fe,Mg, hydrosilicate
CuC0 3 °Cu(OH2)
Cu(CH 3 COO)2 °2Cu(OH)2
Cr20 3 0 2 H2O
no
yes
no
yes
yes
yes
yes
Blue
Azurite
Cerulean blue
Cobalt blue
Egyptian blue
Phthalocyan ine blue
Prussian blue
Smalt
Ultramarine (Iazurite)
2CuC0 3 °Cu(OH2)
CoOonS n02
CoOoAI2 03
CaO °Cu004Si02
C3 2 H 6 N 8 Cu
1
Fe4(Fe(CN) 6 )3
potash glass
Si02, A120 3 , Na20, S
yes
no
no
yes
yes
yes
yes
yes
Brown and black
Asphaltum (bitumen)
Black oxide
Bone black (apatite)
Charcoal
organic
Fe20 3
Ca3 (P04)2 ' carbon
carbon
yes
no
yes
no
I ron oxide pigments
Yellow (goethite)
Red (hematite)
Fe20 3 02H2O
Fe20 3
yes
no
White lead
(basic su lfate)
Zinc oxide
Red and orange
Cad m i u m red
Cadmium red
(Iithopone)
Chrome orange
Realgar
Red lead
Verm ilion
"From Gettens and Stout
( 1 96 )
and Afremow and Vandeberg
( 1 96 )0
3 8003200
cm - 1
22002000
cm -1
1 7001 2 00
cm - 1
1 2001 000
cm - 1
1 000700
cm -1
m
w
m
m
m
w
m
s
s
w
w
w
w
w
w
m
s
m
w
m
m
w
w
w
w
m
w
w
m
m
w
m
m
w
m
m
w
w
120
Chapter
5
commercial formulation containing fillers, such as clay or barium sulfate,
would produce a characteristic spectrum. In this instance, the recorded
spectrum would indicate the fillers and not the actual pigment.
Several reference spectral collections, books, and digitized
spectra ( listed in Appendix I) are available for minerals and pigments;
these are Sadtler Research Laboratories, Sprouse Scientific Systems, Inc.,
Nyquist and Kagel ( 1 97 1 ) , Afremow and Vandeberg ( 1 96 6 ) , Boldyrev
( 1 976), Nakamoto ( 1 9 7 8 ) , and Price and Carlson ( forthcoming).
Mixtures
Most conservation-related samples submitted for IR analysis are mixtures.
Their IR spectra contain the superimposed spectra of each component
present. The intensities of each component's bands are directly propor
tional to the concentration of that component. The resulting spectrum
may be complex, with overlapping bands that obscure those needed for
individual material identification. Thus, the interpretation of a spectrum
from an unsuspected mixture may lead to erroneous conclusions. How
ever, it is often possible to identify at least one component directly, and
then eliminate its absorptions from further consideration. The pattern of
other components, if not initially recognized, may then become clearer.
In paints, pigments are dispersed in an organic binder. This
usually does not hinder the determination of the pigment, but it may
make it difficult to determine the binder if it is present in low concentra
tions. Figure 5.20 illustrates the IR spectrum obtained from a 5 0150
w/w% mixture of calcium carbonate and rabbit-skin glue. Even though
the weight proportion of the two components is equivalent, the relative
intensities of the strongest absorption bands for each component are not
the same, because the absorptivity of each functional group depends on
its dipole moment, bond strength, and molecular environment.
For the analysis of paints, it is helpful if the pigment compo
nent is identified and spectrally subtracted, thus providing a better indica
tion of any binder absorption bands that may have been obscured by the
overlapping pigment absorptions. When the inorganic component cannot
be identified or when the subtraction does not work well, solvent extrac
tions may be useful to physically separate the binder from pigments
before each fraction is reanalyzed ( for technique, see chap. 3 ) . Figure
5 . 2 1 illustrates the IR spectrum obtained for a neat sample of red paint.
The sharp absorptions bands due to a synthetic organic pigment over
lapped the absorption bands for the binder, making it difficult to identify.
After a drop of acetone was placed on the sample and allowed to evapo
rate, the dried residue of the acetone-soluble portion of the paint was
analyzed. The absorption bands created by the red colorant were no
longer noticeable. This spectrum corresponds well with an ethyl acrylate
reference spectrum.
The average detection limit for most materials in a mixture is
5 % . It may range from below 1 % to 3 0 % , however, depending on the
absorptivity of the material and on the number of components in the
mixture. The sensitivity to minor components may be enhanced by the
use of techniques of spectral subtraction, deconvolution, and derivatiza-
121
Spectral I nterpretation
III
I
Rabbit-skin glue
Calcium carbonate
Figure 5.20
I R transm ittance spectra of pure rabbit
skin glue, pure calcium carbonate (calcite) ,
and a mixture contai ning 50% w/w% of
each. The absorption bands for both indi
50/50 w/w%
vidual compounds are present i n the spec
rabbit-skin glue and
calcium carbonate
trum for the mixture, and their respective
absorption band intensities correspond to
the proportion of that material in the
m ixture. In material mi xtures for which
absorption bands overlap, it can be
4000
3600
3200
2800
2400
2000
1 800
1 600
1 400
1 200
1 000
800
600
Wavenumber (cm - 1 )
difficult to identify some components.
tion, as well as solvent extractions. More details about these spectral
manipulation methods are given later in this chapter.
Quantitative Analysis
The intensities of spectral bands are used for quantitative
( :!: 1 % )
and
semiquantitative ( :!:l O % ) IR analysis. Because of potential spectral inter
ferences, sample preparation variations, and sensitivity limitations, it is
difficult to obtain highly accurate quantitative results with IR spec
troscopy. Quantitative analysis of organic compounds is much more
reliably achieved with chromatographic methods. Often, however, semi
quantitative analysis is sufficient to answer the analysis question. In this
case, IR has an advantage, because it can readily supply qualitative and
122
Chapter
1 10
5
Red paint
1 00
90
Q)
<.)
c:
<U
:t::
E
<JJ
80
70
c:
<U
� 60
?f!.
50
40
30
1 10
Acetone extract
1 00
Figure 5.21
90
I R transm ittance spectra for a neat red
paint sample (top) and for the acetonesoluble portion of the sample (bottom).
The absorption bands from the organic
colorant h i nder the identification of the
bind er. A solvent extraction separates
Q)
<.)
c:
<U
:t::
80
E
<JJ
c:
<U
�
?f!.
70
60
some of the binder from the pigment,
allowing for a " cleaner" spectrum to be
collected. The spectrum for the acetone
extract corresponds to an ethyl acrylate
50
40
3000
3500
2500
2000
1 500
1 000
Wavenumber (cm- 1 )
reference spectru m .
semiquantitative analysis results. In order for quantitative calculations to
be performed, however, the material must first be identified.
The capacity of any component to absorb IR radiation is con
stant. This capacity is termed its molar absorptivity. Additionally, the
intensity of any specific absorption band in relation to another is con
stant, because the intensity of an absorption band is directly proportional
to the rate of change in the dipole moment of that particular vibration.
A large change in the dipole moment of the atoms during a vibration will
produce an intense band. Thus, very polar functional groups, such as
those containing halogens, will exhibit intense absorption bands. An
intense absorption band can also be produced by the presence of multiple
functional groups within the molecule, such as CH2 groups in paraffin
wax, that each have the same vibrational energy, such that an additive
effect is created.
There is a linear quantitative relationship between
absorbance and concentration of absorbing molecules:
A
b c
=E =
-
log ( liT)
123
Spectral Interpretation
where: A
absorbance;
molar absorptivity ( a constant for the
= = E= =
molecule); b
sample pathlength; c
concentration; and T
=
transmit
tance ( % T/1 00 ) .
This equation i s called the Beer-Lambert law-or simply
Beer's law-and it is used to determine a relationship between measured
absorptivity, band intensity, and concentration of IR-active functional
groups in the sample. The linear range for the relationship holds for
spectra with a maximum absorption band between 20 and 6 5 % T
( 0 . 7-0.2 absorbance). The equation shows that there is a one-to-one rela
tionship between the height, or intensity (in absorbance units ) , of an
absorption band and the concentration of that molecule. Note that the
linear relationship holds for absorbance and not for transmittance, which
has a logarithmic relationship. Thus, for quantitative work, spectra
should be plotted in absorbance units.
All quantitative IR analyses are done by comparing the
intensity of a specific absorption band, in a bsorbance units, of the
unknown material with the absorbance, or band height, of the same
material in a standard of known concentration. In a mixture of materi
als, the a bsorbances are additive; thus, the total absorbance at any
given wavelength is the sum of the absorptions of the individual com
ponents . Therefore, for quantitative analysis of a material, it is advan
tageous to select an a bsorption band that not only is characteristic of
that material but also is isolated from absorption bands due to other
materials in the sample.
Beer's law shows that sample pathlength is also a factor in
the measurement. For one quantitative method, direct calculation of con
centration, the path length must be either known or fixed. Thus, direct
measurement is normally limited to liquids or solutions that can be ana
lyzed in a fixed-pathlength liquid cell. In this method, the unknown con
centration of an identified single component can be calculated from a
calibration curve. The calibration curve is prepared by analysis of the
same component in solutions, or mixtures, of at least four different con
centrations. An absorption band is selected that is characteristic of the
component of interest and that is free from interferences. Then a plot is
made of the absorbance value for that band versus the concentration of
the component in each solution. The concentration of the sample is
determined by comparing the intensity of that particular band in its spec
trum with the calibration curve. The intensity of the band is measured as
the absorbance difference from its maximum to its baseline. The baseline
is drawn where the pen tracing would go if the band were not present
( Smith 1 979 ) . Integrated, or total-area, measurements of the absorption
band are rarely needed, since intensity measurements can be made more
reproducibly and accurately ( Smith 1 979 ) . Because the pathlength cannot
be determined precisely, this method is not used for films and pellets.
The absorbance ratio method is used when the pathlength of
the sample cannot be readily determined. The method works well for
films, pellets, and diffuse or internal reflection measurements. For this
method, at least two components (A and B) must be in the sample
matrix, and each must have an absorbance band that exhibits minimum
124
Chapter
5
interference. Because the components are present in the same sample, the
pathlength is the same and is no longer a variable. The calibration curve
is generated from at least four spectra obtained from mixtures of the
components in different proportions. The ratio of the intensities of the
two bands of interest ( IA/IB ) is plotted versus the ratio of their concentra
tions ( CA/CB ) . Once the curve is generated, the ratio of the concentration
of the components in the unknown sample can be determined, since the
sum of their concentrations equals unity, or 1 00 % . Thus, the specific
concentrations for each component can be easily calculated.
The absorbance ratio method was applied to the study of
archaeological wood deterioration by Kirillov and Mikolajchuk ( 1 9 9 0 ) .
Ferrus, Pages, a n d Diez ( 1 9 8 1 ) used quantitative analysis for the exami
nation of kaolin-casein coatings on papers. Other methods, such as the
internal standard method used by Biscontin and Volpin for the analysis
of calcium oxalate films ( 1 9 8 9 ) , are also available. For other methods of
quantitative analysis, see the IR spectroscopy atlas published by the
Chicago Society for Paint Technology ( 1 9 8 0:53-5 8 ) and Smith
( 1 979:2 1 9-6 8 ) .
Mathematical Manipulations of Spectra
The linear proportionality of a material's concentration to its absorbance
band intensity ( Beer's law) is the basis for many of the IR data processing
algorithms, such as spectral subtraction, spectral searching, and factor
analysis. Other routines, such as Fourier self-deconvolution, can aid in
the resolution of bands.
Subtraction techniques
Computer spectral subtraction methods are used to separate spectra of
components in a mixture, to remove bands due to impurities, to confirm
the identity of a sample, and to detect small changes in a sample . When
one component is identified, its pure spectrum ( in absorbance units) is
then multiplied by a scaling factor and subtracted out, and the remaining
spectral bands are examined for any differences. This is known as scaled
absorbance subtraction.
Typically, an Autoscale subtraction computer routine esti
mates a scaling factor based on the integrated areas of several peaks.
While this may be a good estimate, the best method for spectral subtrac
tion is to select visually a single band of the component to be removed in
both spectra, then null out that band ( Griffiths and de Haseth 1 9 8 6 ) . The
resultant difference spectrum should be evaluated closely to see which
bands still exist and to determine if there are other potential components
not initially considered.
When subtraction is used to confirm the identity of a mate
rial, its reference spectrum is subtracted from the sample spectrum; if the
difference is zero, then it is clear that the two spectra are of the same
compound. This is one method used by search routines to check varia
tions between an unknown spectrum and the reference spectra.
Spectral Interpretation
1 25
Difference spectra, resulting from spectral subtraction, are
useful for the evaluation of changes in a material due to chemical reac
tions or aging. The difference spectrum will show only the regions of
changing absorption, while the molecular features that remain constant
are removed by the subtraction operation.
For optimum subtraction results, the two initial spectra
should be recorded from samples prepared and analyzed in the same
manner. Their maximum absorption bands should be no more than 0 . 7
absorbance units ( n o less than 20% T). This guideline ensures that the
components' concentrations are within the linear range covered by Beer's
law. Slight changes in band positions or shapes can result in derivative
like bands or positive residuals occurring in the difference spectrum.
These artifacts may be incorrectly attributed to the presence of minor
components. For more information on the limitations of spectral subtrac
tion and its applications, see Koenig ( 1 992) and Bartick, Corbett, and
McClure ( 1 9 8 2 ) .
Figure 5 .22 illustrates the use of spectral subtraction for the
identification of a minor component. The spectrum on top (A) is shellac
plus a small amount of an unknown material, indicated by the bands at
1 8 00 and 8 70 cm- l . The middle spectrum ( B ) of pure shellac was spec
trally subtracted from the top spectrum, and the resultant spectrum ( C ) ,
which corresponds t o calcium carbonate, is shown a t the bottom.
Resolution enhancement methods
IR absorption bands are relatively broad and may overlap one another.
This is particularly true for the spectra of mixtures. Resolution enhance
ment methods can artificially narrow the width of the bands and thus
minimize overlap. Various mathematical methods, such as derivative
spectroscopy and Fourier self-deconvolution, are iterative optimization
processes performed on the interferogram. The operator selects band
shape and bandwidth parameters; the maximum amount of bandwidth
reduction is determined by the initial resolution at which the spectrum
was measured.
In derivative spectroscopy, the measured absorbance spectrum
is first transformed back into an interferogram. Then the computer multi
plies it by a function to compute the nth derivative. While any order of
derivative may be calculated, the even-order functions (2, 4, etc. ) provide
the better resultant spectra. The second derivative is the most commonly
used. The resultant spectrum will have sharper bands than those of the
original spectrum. Drawbacks are that strong bands will have side lobes
and that spectrum noise is increased. Figure 5 .23 illustrates the use of
derivative spectroscopy to increase the resolution of overlapping hydro
carbon bands.
A deconvolution program may also help elucidate information
in a spectrum. It operates on two or more overlapping bands to reduce
the line width of the individual components and therefore to improve the
resolution of each band up to three times ( Kauppinen et al. 1 9 8 1 ; Koenig
1 992). Convolution is a broadening function that occurs in the produc
tion of a spectrum and changes the intrinsic line shape of the absorption
126
Chapter
5
2000
1 800
1 600
1 400
1 200
1 000
700
1 000
700
1 000
700
Wavenumber (cm- 1 )
.�'"E'" B
Q)
u
c
rn
c
J!=
�
2000
1 800
1 600
1 400
1 200
Wavenumber (cm-1 )
Figure 5.22
= C) for the identification of a
A n example of spectral su btraction
(A - B
minor component. Slight d ifferences
between the top spectrum (A) of a shellac
and calcium carbonate mixture, and the
middle spectrum (B) of shellac were noted.
The middle spectrum (B) was su btracted
from the top spectru m ; the resultant spec
trum (C) corresponds to reference spectra
for calcareous materials.
2000
1 800
1 600
1 400
1 200
Wavenumber (cm - 1 )
into peaks ( bands ) . Deconvolution is designed to correct for the broaden
ing function and thus narrow the bands. The optimum use of deconvolu
tion requires information about the true width of the absorption band,
which is usually not known. If the spectrum is under-deconvoluted,
little improvement in resolution will result. If the spectrum is over
deconvoluted, extraneous side lobes, as well as distortions in band
intensities, will be produced. Since the different IR bands have different
127
Spectral Interpretation
Original spectrum
Figure 5.23
An example of derivatization , one method
used to increase the effective resolution of
a spectrum. The overlapping hydrocarbon
bands for a silicone oil and hyd rocarbon
Second derivative
oil mixture are shown (3050-2800 c m - ' )
for the original transm ittance spectru m ,
the first derivative, and the second deriva
tive. The second derivative is most often
used, since the absorption band maxima
are near their original positions. Derivati
zation changes the relative intensities of
the bands, as well as increases the noise
3040
3020
3000
2980
2960
2940
2920
2900
2880
2860
2840
2820
2800
Wavenumber (cm- 1 )
level of the spectru m .
inherent bandwidths, it is impossible to optimally deconvolute all bands.
Thus, since the same deconvolution width is used for the entire spectrum,
some bands may be overprocessed, while others are underprocessed.
Negative bands may appear, and the signal-to-noise ratio is decreased.
An example of deconvolution is shown in Figure 5 .24. A
sample of a mastic-oil film from the Gettens and Stout Collection, dated
1 934 (prepared on a glass plate as a dried film made from 5 cc oil in
1 00 cc ethanol, with 33 g mastic ) , was analyzed. Even though the com
ponents of the sample were known, because of the low amount of oil, the
bands specific for oil were only slightly recognizable after deconvolution
was performed.
Summary
Characterization of a material class for a pure sample is well within the
realm of IR analysis. This chapter, as an introduction to skills and meth
ods important in spectral interpretation, includes graphs, tables, and dis
cussion aimed at facilitating spectral analysis. Initial examination of
128
Chapter
5
.,-
0.30
Figure 5.24
An example of deconvolution, another
method used to increase the effective res
olution of a spectru m . The original (top)
Q).0<{<.)ceno(f)
and deconvoluted (bottom) absorbance
Deconvoluted
spectra are shown for a sample contai n i n g
jJ�
+-
a mixture o f oil in mastic. Resolved bands
due to the oil are marked with asterisks.
However, because of the low concentra
tion of oil in the sample, its absorption
bands are poorly defi ned, even after
0.29
1 800
1 000
700
Wavenumber (cm- 1 )
deconvolution.
spectra quality is followed by a discussion of information gleaned from
the spectral regions and spectra-structure correlations. In-depth informa
tion is then presented for the interpretation of IR spectra for natural
products, synthetic resins, and colorants that are often found in samples
from art materials and conservation treatments.
Samples from works of art, however, may be complex mix
tures of components that are difficult to completely identify by IR spec
troscopy alone. However, IR spectral analysis can characterize the
material class (es} present within the sample and thus supply a basis for
the selection of a secondary analysis method for further separation of
sample components and their identification. For example, knowledge of a
sample's component classes ( oil, protein, carbohydrate, etc . ) is fundamen
tal to the selection of an appropriate chromatographic analysis protocol.
Positive identification by IR spectroscopy is often limited by
the availability of relevant reference spectra. It is important to have a
spectra collection that simulates the probable set of unknown materials.
This is especially true for complex samples and mixtures. For the field
of art conservation, it is also desirable to have a spectral collection of
aged reference materials. Thus, an extensive set of relevant citations
are presented.
While IR spectroscopy is a valuable method for the
identification of an unknown, the spectra and the method of analysis
must be examined critically before any conclusions are made. Computer
spectral search routines can be very helpful, but the computer can never
make the final decision. Instead, the analyst applies j udgment to draw
conclusions based on information derived from sampling, analysis, and
interpretation.
Spectral Interpretation
1 29
Additional Reading
Al len, R.
0.,
and P. Sanderson
1 9 8 8 . Characterization of epoxy glues with FTIR. Applied Spectroscopy Reviews
2 4 : 1 75-87.
American Society for Testing Materi als (ASTM)
1 99 1 . Standard Practice for General Techniques of Infrared Quantitative Analysis.
ASTM E 1 68 - 8 8 . Annual Book of ASTM Standards, vol. 1 4-0. Philadelphia: ASTM.
Bellamy, L. J .
1 975. Advances in Infrared Group Frequencies. London: Chapman and Hall.
1 980. The Infrared Spectra of Complex Molecules. 2d ed. London: Chapman and Hall.
Chicago Society for Coating Technology
1 98 0 . An Infrared Spectroscopy Atlas for the Coatings Industry. Philadelphia:
Federation of Societies for Paint Technology.
Colthup, N. B., L. H . Daly, and S. E. Wiberley
1 990. Introduction to Infrared and Raman Spectroscopy. 3d ed. Boston:
Academic Press.
Farmer,
V. c.,
ed.
1 974. The Infrared Spectra of Minerals. Mineralogical Society Monograph 4. Surrey,
U.K.: Adlard and Son.
S i lverstein, R. M., G. C. Bassler, and T. C. Morri l l
1 9 9 1 . Spectrometric Identification of Organic Compounds. 5th ed. New York: John
Wiley and Sons.
Chapter
6
Case Studies
Over thirty years ago, Jacqueline Olin stated that " infrared spectropho
tometry is becoming an increasingly important method in the analysis,
authentication, and preservation of paintings and ancient artifacts " ( Olin
1 96 6 ) . Since that time, IR spectroscopy has been employed in several
significant studies of museum materials, and it is now the leading choice
for analysis of most organic, and of many inorganic, materials in art con
servation research. IR spectroscopy enjoys such standing because it can
be used for the analysis of small amounts of nearly any substance, thus
encompassing the broad range of materials and restrictive sample sizes
encountered in artifact analysis. The applications of IR are multifaceted,
covering not only the identification of materials but also the evaluation
of condition and the monitoring of chemical reactions.
Identification and Characterization of Material s
IR spectroscopy has long been a primary tool for the identification of
art and archaeological materials. When Gettens promoted the technical
examination of art in 1 952, IR spectroscopy was included as a technique
for the analysis of artifacts and paintings ( Gettens 1 952). In 1 96 8
Masschelein-Kleiner and coworkers selected I R analysis as one method i n
a scheme for the identification o f binding media, varnishes, a n d adhesives
(Masschelein-Kleiner, Heylen, and Tricot-Marckx 1 96 8 ) . In 1 969 Olin
and coworkers reviewed favorably the emerging use of IR spectroscopy
for the analysis of art obj ects ( Olin, Salmon, and Olin 1 96 9 ) . Then, in
1 977, Low and Baer showed the increased sensitivity of Fourier transform
infrared ( FT-IR) spectroscopy for the analysis of many natural organic
materials ( Low and Baer 1 977). In 1 9 8 9 Roelofs presented an analytical
schematic for the identification of varnishes, media, and dyestuffs, using
IR in a combination of modern techniques (Roelofs 1 9 8 9 ) .
One important application for I R spectroscopy is the deter
mination of components in paint samples. Birstein used IR in several
studies to determine the binders and pigments in Asian wall paintings
and Egyptian tomb paintings, as well as to examine the aging character
istics of gelatin ( Birstein 1 9 75, 1 97 8 ; Birstein and Tul'Chinskii 1 9 77).
Delbourgo used IR to analyze fresco painting cross sections (Delbourgo
131
Case Studies
1 9 72 ) . Both egg tempera a n d drying oils were found as media in Gothic
panel paintings that were part of the main altar in the church of
Tingelstad, Norway (Plahter, Skug, and Plahter 1 974 ) . Riederer used IR
to examine the techniques and materials of early medieval mural paint
ings in Turkistan ( Riederer 1 977) . Kobus describes the use of both IR
and scanning electron microscopy with energy dispersive spectroscopy
( SEM-EDS ) for the microanalysis of small paint samples ( Kobus 1 9 8 7 ) .
A technical examination of Gerard Dou's The Young Mother used I R and
gas chromatography ( GC ) ; results indicated the presence of bitumen (van
der Loeff and Groen 1 9 9 3 ) .
Reference spectra of ethnographic materials are often gener
ated as part of a corresponding technological study, since commercial
libraries do not contain spectra of these materials. To examine the
introduction of rice to the Pacific islands, Hill matched the extract of
an archaeological specimen from Borneo to reference spectra of rice
extracts ( Hill 1 9 8 3-8 4 ) . As part of an investigation in the use of veg
etable resins on Congo ceramics, a series of reference spectra for native
resins were collected and compared to samples from decorative coatings
on the ceramics ( Hexter and Hopwood 1 9 9 2 ) . Pigments and media
from 1 ,346 samples of historic Native obj ects were analyzed by the
Canadian Conservation Institute to form a database characterizing
material usage by tribes, regions, and time periods ( Miller, Moffatt,
and Sirois 1 9 9 0 ) .
Several technical studies have used I R spectroscopy i n con
j unction with other techniques to examine archaeological obj ects.
Delbourgo and Gay analyzed organic remains found in archaeological
excavations in Sudan ( Delbourgo and Gay 1 9 6 8 ) . IR spectroscopy was
used by Maniatis and coworkers to determine the hydration state of
clays in low-fired terra-cotta statues from Greece (Maniatis, Katsanos,
and Caskey 1 9 8 2 ) . Duraiswamy and coworkers later used this technique
to determine the firing temperature of clays from excavations in India
(Duraiswamy, Ramaswamy, and Venkatachalapathy 1 99 2 ) . X-ray
fluorescence, atomic absorption, and IR studies were performed on tile
and wall fragments from ancient Roman settlements ( Blasius et al.
1 9 8 3 ) . IR was used for the initial examination of cosmetics from a
Thracian tomb in Bulgaria; that examination was followed by chro
matography for the final identification of individual components
( Zolotovich and Popov 1 9 6 9 ) .
I R spectroscopy is ideal for the identification o f synthetic
resins used as coatings and binders. Jayme and Traser collected reference
spectra for paper coatings and fillers and used them for the identification
of coated papers (Jayme and Traser 1 97 1 ) . Cellulose nitrate has been
identified as an emulsion used on early microphotographs (Newman and
Stevens 1 9 77). Stringari characterized acrylics used in artist paints
( Stringari and Pratt 1 99 3 ) . Sharpless used IR to identify the plastics and
their additives when he extensively characterized the effects of storage
materials and cleaning products on the deterioration of coins in museum
collections ( Sharpless 1 9 8 0 ) .
1 32
Chapter
6
IR spectroscopy can also help in the identification of some
organic colorants and dyes (Masschelein-Kleiner and Maes 1 97 8 ) .
Berberine, a traditional yellow Japanese dye, has been well characterized
by fluorescent and IR studies ( Matsuda 1 9 8 6 ) . Garrido used IR to differ
entiate between Maya blue ( indigo on clay) and malachite for multiple
blue painted Mayan obj ects ( Garrido 1 96 9 ) . IR was also used as one
method in the identification of royal purple dye, an indigo colorant used
in antiquity found in the interior of jars in a thirteenth-centurY-B.c.E.
Lebanese archaeological site ( McGovern and Michel 1 99 0 ) . Roelofs and
coworkers di scussed IR in their comprehensive study of the advantages
and disadvantages of several analytical methods for the identification of
dyestuffs ( Roelofs et al. 1 9 8 7 ) . Very small samples of archaeological
fibers and dyes have been analyzed by IR microspectroscopy ( Lang et al.
1 9 8 6 ; Matsuda and Miyoshi 1 9 89; Jakes, Katon, and Martoglio 1 990;
Martoglio et al. 1 990; Jakes, Sibley, and Yerkes 1 994).
Corrosion and patinas on metal surfaces are often a mixture
of materials that can be characterized by IR. Tennent and Antonio used
IR to characterize bronze disease and its products (Tennent and Antonio
1 9 8 1 ) . Giangrande presented in a paper a selection of reference spectra
for bronze corrosion products ( Giangrande 1 9 8 8 ) . IR was one method
used by Jakes and Howard to characterize the mineralization of textiles
found encrusted on bronze implements from the Chinese Shang dynasty
(Jakes and Howard 1 9 6 8 ) . Schrenk found corrosion below protective
coatings on Benin bronzes ( Schrenk 1 9 9 1 ) . Koltai used IR to determine
corrosion products on a Roman silver fibula ( Koltai 1 9 8 4 ) . Another
study used IR to examine the corrosion products of lead exposed both
to controlled conditions and to an outdoor environment (Tranter 1 9 76 ) .
Corrosion processes occurring on stained-glass windows have also been
examined with IR spectroscopy ( Bettembourg 1 9 8 8 ; Fuchs, Romich, and
Schmidt 1 99 0 ) . IR spectroscopy has been used to investigate the corro
sion inhibition capabilities of metal coatings (Tobe et al. 1 9 74; Ito and
Takahashi 1 9 8 5 ) . Efflorescence on mollusk shells was characterized by
Tennent and Baird, who used IR, X-ray diffraction ( XRD ) , thermal
analysis, and nuclear magnetic resonance ( Tennent and Baird 1 9 8 5 ) .
IR spectral imaging i s a special technique useful i n the IR
spectroscopic analysis of materials. Imaging technologies use multi
dimensional spectroscopic processing to create compositional maps
of samples. Familiar examples are elemental imaging on an electron
microscope and magnetic resonance imaging for medical diagnoses.
Characterization of materials with IR mapping micro spectroscopy ( also
known as functional group mapping) has been developed for several
years (for history and more information, see Harthcock and Atkin 1 9 8 8 ) .
Derrick and coworkers illustrated the application of IR spectral imaging
to the characterization of paint cross sections (Derrick 1 99 5 ) . IR map
ping combines the analytical capabilities of an IR microscope with a
computer-controlled, motorized stage and appropriate software pro
grams, in order to identify, as well as locate, various types of compo
nents, anomalies, and defects in materials.
1 33
Case Studies
Deterioration Studies
While it is easy to think of IR spectroscopy as a tool for the identifi
cation of materials, it is often used for other studies, such as the moni
toring of chemical reactions, the determination of chemical changes and
degradation, the ascertaining of damage from specific conditions, and
the evaluation of material stability. Common exposure conditions (ultra
violet [UV] radiation, elevated temperatures, oxygen, high humidity,
reactive vapor, and dirt) cause deterioration and damage to some materi
als. However, not all materials react to any one parameter in the same
fashion. IR spectroscopy can be used to increase understanding of
degradation processes, causes, and rates of change; this knowledge can,
in turn, aid in the development of conservation strategies to extend the
lifetime of an obj ect.
Feller examined the Fade-Ometer-induced alterations occur
ring in the IR absorption spectra of natural resins and afterward con
cluded that it is necessary to have reference spectra of aged resins for
comparison of samples from aged obj ects ( Feller 1 95 9 ) . In another accel
erated aging study, Kenj o, who used IR spectrometry to examine the
effects of increased temperature and UV light on Japanese lacquer, found
that the outer surface of lacquer-covered obj ects exhibited measurable
oxidation (Kenjo 1 9 76 ) . The mechanism by which soluble nylon becomes
insoluble has been studied: the change in solubility was found to be due
in part to photooxidation and hydrolysis (Bockoff et al. 1 9 84; Fromageot
1 9 90; Fromageot and Lemaire 1 9 9 1 ) . Oosterbroek and coworkers used
IR to relate chemical and mechanical changes (crack formation and stress
development) in organic coatings ( Oosterbroek et al. 1 9 9 1 ) . Both IR and
UV/visible (UVNis) spectroscopies were used to study the effect of heat
and light aging on three formulations of Paraloid B-72 adhesives (Butler
1 9 8 8 ) . In some wood degradation studies, the ratio of cellulose to lignin
was measured by IR (Kosik, Luzakova, and Reiser 1 9 72; Pecina and
Kommert 1 9 85; Mikolajchuk et al. 1 9 87; Kirillov and Mikolajchuk
1 9 9 0 ) . Hon used IR spectroscopy to study the degradation of paper
documents ( Hon 1 9 8 9 ) . IR has also been used to study the structural
stability of hair samples from Egyptian mummies (Lubec et al. 1 9 8 7 ) .
The weathering o f stone due t o the outdoor environment and
to pollutants has been well studied with IR analysis. Reflection IR mea
surements were used to examine the effects of temperature, relative
humidity, and pollutants on marble ( Sramek 1 9 7 8 ; Faraone 1 9 87; Rao
1 9 82, 1 9 8 4 ) . The effects of sulfur dioxide pollutants and the resulting
stone deterioration were further assessed ( Eastes and Salisbury 1 9 8 6 ;
Zappia e t a l . 1 992; Connor and Girardet 1 992 ) . Accretions, salt
deposits, and weathered surfaces on stone sculptures and buildings were
identified with IR spectroscopy ( Frediani and Matteoli 1 9 78; Bradley
1 9 8 7; Abd EI-Hady 1 9 8 8 ; Domaslowski and Kesy-Lewandowska 1 9 8 8 ;
Shoeib, Roznerska, and Boryk-Jozefowicz 1 9 90; Blanco et al. 1 99 1 ) .
Calcium oxalate has been investigated as a weathering product formed
by the action of lichens on stone ( Gorgoni, Lazzarini, and Salvadori
1 99 2 ) . Other studies have quantitatively measured calcium oxalate
1 34
Chapter
6
(Biscontin and Volpin 1 9 8 9 ) and examined the stability of calcium
oxalate hydration states (White and Ai 1 99 2 ) , as well as determined its
potential for protecting underlying stone (Matteini, Moles, and
Giovannoni 1 994). In the study of the reversibility of fluoropolymer
treatments of stone, Camaiti and coworkers used IR spectroscopy to
determine the extent of polymer removal ( Camaiti et al. 1 9 9 1 ) .
The Case Studies
Ten case studies are presented below. Note that for Case Studies 1 -6, IR
is used to characterize unknown samples. Case Studies 7-1 0 show how
IR can be used to monitor changes and examine degradation in several
types of materials.
Case Study
1:
U ltramarine pigments
The most common method for the identification of an IR spectrum of an
unknown sample is its direct comparison to a reference material spec
trum. When the materials are the same, the intensity and position of all
absorption bands will correspond. If the unknown spectrum is missing
bands that the reference contains, then that reference can be unequivo
cally eliminated. However, if the two spectra correspond except for the
addition of one or more bands in the sample spectrum, then the interpre
tation becomes complex. As shown in this case study, the analyst must
determine whether these additional bands are due to a different material,
to an added component, or to a contaminant.
Background
Ultramarine blues are composed of complex sodium aluminum sulfosili
cates and are one of the oldest blue pigments (Moser 1 9 7 3 ) . Natural
ultramarine is an expensive blue pigment produced from the semi
precious stone lapis lazuli. The colorant can be separated from extrane
ous minerals in the stone by a time-consuming process. As described by
Cennino Cennini in the fifteenth century, the powdered lapis was mixed
with a wax-oil-resin mixture and kneaded in a weak lye solution
( Cennini 1 9 6 0 ) . The dough retained the extraneous particles, and the
blue particles settled out. In the 1 820s, a commercial process for syn
thetic ultramarine was developed that produced a very pure, deeply col
ored, fine-particle material. Optical microscopy is used to distinguish
between the natural and synthetic ultramarine particles based on the size
and shape of the particles. Other analysis methods (X-ray fluorescence,
SEM-EDS, XRD ) commonly used for the identification of pigments can
not readily differentiate between natural and synthetic ultramarine.
During routine IR microanalysis of pigments and binders from
a sixteenth-century Italian painting ( Venus and Adonis by Titian, J. Paul
Getty Museum, Los Angeles ), it was noted that the IR spectrum obtained
from a natural ultramarine blue particle corresponded to a reference spec-
135
Case Studies
trum for natural ultramarine, with the exception of an unexpected addi
tional absorption band at 2340 cm- t . Further analyses showed that all the
blue particles in that sample and in paint samples from two other paint
ings (Presentation in the Temple by Mantegna, Staatliches Museen, Berlin,
and Madonna with Child by Mantegna, Accademia Carrara, Bergamo,
Italy) contained this absorption band (Fig. 6 . 1 ) . Since this region of the IR
spectrum contains rarely found functional groups ( e.g., cyano and carbon
carbon triple bonds ) , the first concern after the unusual absorption band
was observed was that Prussian blue ( ferric ferrocyanide, Fe4[Fe( CN) b
6
developed in the eighteenth century) was in the sample.
Analysis question
What material is producing the absorption band at 2340 em- I , and is it
normally found in spectra for natural ultramarine blue particles?
Method
IR microanalysis was used for this study. The size of the individual blue
particles ranged from approximately 10 to 40 ,....,m in diameter after flatten
ing. Thus, each individual blue particle could be selected directly for
analysis by use of the adjustable apertures on the microspectrophotometer.
VenusandAdonis
Pres ntaioni theTemple
Madon awithChifd
by Titian
Figure 6.1
IR transm ittance spectra for blue particles
of natural ultramarine obtained from th ree
2340
by Mantegna
2340
by Mantegna
fifteenth- and Sixteenth-century Italian
paintings (Venus and Adonis by Titian,
J.
Paul Getty Muse u m , Los Angeles;
Presentation in the Temple by Mantegna,
Staatliches Musee n , Berl i n ; and Madonna
with Child by Mantegna, Accademia
Carrara, Bergamo, Italy) . Each spectrum
exhibits an absorption band at 2340 cm- 1
that is not due to carbon dioxide.
4000
3000
2000
Wavenumber (cm- 1 )
1 500
1 000
1 36
Chapter
6
Analysis
For this example ( and all following case studies, except as noted), each
particle was placed on a barium fluoride ( BaF2 ) window, flattened with a
metal roller, then analyzed with transmitted radiation. A Spectra-Tech
IRj.LS microprobe was used for the IR analysis ( see Suppliers ) . It is
equipped with a narrow-band, cryogenically cooled mercury-cadmium
telluride ( MCT) detector. The spectra are the sum of 200 scans collected
from 4000 to 800 cm- t at a resolution of 4 cm- t . The IRJlS and the
sample were continually purged with dry, carbon dioxide ( C0 2 )-free air.
This factor is important, because the absorption band of interest occurs
in the same region as the CO 2 doublet at 2340 cm- t .
Results
Comparison of the sample spectra with the IR reference spectra for pig
ments containing cyano stretches ( Prussian blue and bone black) showed
that the small absorption band in the natural ultramarine at 2340 cm- t
was distinctly different from the cyano stretch that occurs near 2 1 00
cm- t ( Fig. 6.2 ) . A literature search showed that Orna and coworkers, in
the analysis of samples from a fourteenth-century Italian manuscript,
published a natural ultramarine spectrum that contained the small
absorption band near 2340 cm- t ( Orna et al. 1 9 8 9 ) . Subsequent analyses
at the Getty Conservation Institute ( GCI) have identified this absorption
Blue particle from
Pres ntaioni theTemple
by Mantegna
Natural ultramarine
201 0
Pruss ian blue
Figure 6.2
Comparison of IR transmittance spectrum
obtained from a blue particle on a
2090
fifteenth-century Italian painting
(Presentation in the Temple by Mantegna)
4000
3000
2000
with reference spectra for natural ultrama
rine, ivory black, and Prussian blue.
Wavenumber (cm- 1 )
1 500
1 000
Case Studies
1 37
band in samples from four other Italian paintings from the fifteenth and
sixteenth centuries.
Examination of over thirty samples of ultramarine showed an
intriguing trend. The absorption band at 2340 cm-1 occurred only in
lapis lazuli and natural ultramarine obtained from the Badakhshan mines
in Afghanistan. The band did not occur in any synthetic ultramarine
samples or in any samples of lapis lazuli and lazurite obtained from
known sources in Siberia (former USSR) or Chile ( Fig. 6.3 ) . Thus, it
appears that the presence of this particular absorption band in an ultra
marine sample shows that it is a natural product whose source may be
the lapis lazuli mines in Afghanistan.
The Badakhshan mines, the most famous source for lapis
lazuli, have been worked for over six thousand years (Webster 1 9 8 3 ) .
The blue color i n the lapis i s caused b y two minerals, lazurite and
hauyne. Geologically, the lapis from the Afghanistan mines contains pre
dominantly hauyne ( Banerjee and Hager 1 992 ) . Hauyne contains a
Lapis lazuli
(Badakhshan, Afghanistan)
Lapis lazuli
(Siberia)
Lazurite
(Chile)
Synthetic ultramarine
(Kremer-Pigmente)
Figure 6.3
Comparison of IR transm ittance spectra
for lapis lazuli samples obtained from
Badakhshan, Afghanistan; Siberia; and
Chile, with a spectrum for synthetic ultra
marine blue. Only samples from the m i nes
of Badakhshan exhi bit the absorption band
at 2340 cm- 1 ,
4000
3000
2000
Wavenumber (cm - ' )
1 500
1 000
1 38
Chapter
6
higher concentration of calcium and sulfur than other types of sodalite
minerals, such as lazurite. It is most likely the sulfur, S+ 6 , that produces
the unique IR absorption band at 2340 cm- I . While the literature states
that the largest European source of lapis was Afghanistan, there are a
few small mines of hauynite found in Italy (Taylor 1 96 7 ) . Samples from
the Italian mines have not yet been analyzed.
Resolution
Based on the extensive number of IR spectra collected of natural ultra
marine samples, it was concluded that the blue particles in the fifteenth
century paint samples were natural ultramarine. Furthermore, it is
possible that the natural ultramarine in these samples came from the
Badakhshan mines. This finding is consistent with known supplies and
trade routes for that time period.
Case Study
2:
Creosote lac resin
Prior to the analysis of an unknown material, a logical sequence is to
obtain information both on the history of the obj ect and on the sus
pected composition of the sample( s ) . The second step is to locate refer
ence samples or spectra that correspond as closely as possible to that
projected set of materials. The following example shows a sample that
would have been difficult to identify without the contextual information
about the obj ect and without the correct reference materials ( all provided
at the time of the analysis request by Holcomb and Dean 1 9 9 3 ) .
Background
Native Americans in the southwestern United States used a variety of
natural materials as adhesives and coatings on their pots, baskets, and
other vessels . These include pitch or sap from several pines, j unipers, and
brittlebush; animal fats and glues made from horns, skin, or bone from
deer or mountain sheep; and resin from creosote bush lac scale insect
(Sutton 1 99 0 ) . Another source also states that "holes or cracks in pottery
were repaired with creosote bush lac or pitch" ( Felger and Moser 1 9 8 5 ) .
The creosote bush grows i n the deserts o f California,
Arizona, New Mexico, Baja California, and northern Mexico. The resin
is found on the outside of branches on infected plants and can be easily
removed by twisting it off the branch. The resin is hard and brittle, but it
is thermoplastic and becomes workable when heated; thus it must have
been applied hot. It hardens on cooling to form a strong bond. Records
show that its was used to adhere stone arrowheads in their shafts and to
mend broken bowls ( Coville 1 8 92 ) .
Found on the branches o f the creosote bush, this insect resin
is sometimes incorrectly labeled as creosote gum, when in actuality, it is
a secretion produced from the female creosote lac scale insect. Lac scale
insects compose a small family of species that exude a resinous substance
known as lac. Shellac is the most common commercial product, but exu
dations from these insects are also used to produce medicines and dyes.
In the eastern Mojave Desert, several previously undiscovered
Native American artifacts were recovered by cultural resource specialists
1 39
Case Studies
of the U.S. Bureau of Land Management. A reddish-brown material was
found on the exterior surface of one ceramic pot, near a small crack. The
repair, on an otherwise intact pot, must have been done when the pot
was in use. Thus, it was important to identify the adhesive in order to
increase understanding of the culture, technology, materials usage, and
perhaps even trade patterns of the native inhabitants in the area.
Analysis question
What is this adhesive material, and does it correspond to any materials
indigenous to the region ?
Method
IR microanalysis was used for this study because of convenience and
availability. Sufficient sample sizes-almost a milligram of sample and a
gram of reference material-were provided for analysis, so other IR
analysis methods, such as potassium bromide (KBr) pellets or DRIFTS
could have been used if needed. The preparation of small fragments of
the samples on BaF2 windows for microanalysis can be readily followed
with selective solvent extraction on the same substrate, since BaF2 is inert
to most solvents.
Analysis
The instrument parameters and analysis conditions were the same as
those specified in Case Study 1 .
Results
IR spectra were collected on a small sample of the adhesive from the
object. Figure 6.4 shows the spectrum obtained from the sample, as well
as reference spectra for creosote lac, j uniper pine resin, and pinon pine
resin. After the bulk sample was analyzed, solvent extraction tests were
done to check the solubility of the sample and to separate any impurities.
A small drop of ethyl acetate was placed on the sample and an additional
spectrum obtained from the soluble portion of the resin that collected in
a ring around the sample ( Fig. 6 . 5 ) . A parallel reference spectrum col
lected for the ethyl acetate-soluble portion of creosote lac is also shown.
The solubility test and IR spectra show that the extracted residue of the
sample corresponds well to the extracted residue of creosote lac.
The extraction step is often necessary for the identification of
aged, natural products. These materials may contain extraneous materi
als, such as dirt and insect and animal residues, as well as some insoluble
fractions of the material that have chemically altered over time (i.e., oxi
dized) . Separation of the soluble fractions aids in the interpretation of a
mixture of materials, as well as provides solubility information.
Resolution
The IR spectra indicated that the adhesive used on the Native American
ceramic pot did indeed correspond well to creosote lac. The subsequent
analysis of the solvent-soluble portions of both samples confirmed the
identification. Without the submission of the reference creosote resin for
1 40
Chapter
6
Pinon
pine resin
Figure 6.4
IR transm ittance spectra for bulk adhesive
samples obtained from a Native American
ceramic pot, along with reference spectra
4000
3000
2000
1 500
1 000
for creosote lac, j u niper pine resi n , and
Wavenumber (cm- 1 )
pinon pine resin .
Ethyl acetate extraction of pot repair material
(,)
OJ
c
co
.�
Ethyl acetate extraction of creosote lac
rn
c
co
�
�
Figure 6.5
I R transm ittance spectra of the ethyl
acetate-soluble portions of the adhesive
4000
3000
2000
from the ceramic pot and the creosote lac
res i n . The two spectra correspond well.
Wavenumber (cm- 1 )
1 500
1 000
141
Case Studies
direct comparison, this analysis would only have been able to classify the
sample as a natural resin. IR reference spectra for natural products, such
as creosote resin, are rarely contained in commercial IR libraries.
Case Study
3:
Chumash Indian paints
IR spectroscopy functions well as a screening tool to characterize and
compare many types of materials. This screening can be applied to divide
large sample sets into similar compositional groups, as well as to supply
a basis for the selection of secondary analysis methods. As shown in this
example, IR is used to determine a sample's component classes ( oil, pro
tein, carbohydrate, etc . ) prior to further specific identification.
Background
The south-central region of the California coast was inhabited by the
Chumash Indians for over a thousand years. The Chumash were skillful
artisans, and their rock art is well known. Most often found in the Santa
Barbara and Ventura County mountains, some of these paintings reach
sizes as large as 40 feet in length and have polychrome designs of six col
ors ( Grant 1 99 3 ) . Some of the motifs are detailed, showing lizardlike
creatures and other animals.
Ethnographic information suggests that the Chumash and
other Indian groups of central and southern California may have used
the paintings as part of a ritualistic procedure and that the paintings may
have been related to astronomical observations. Early investigators were
struck by the durability of the paintings and were curious as to the tech
niques used to make them. In 1 8 8 3 , Garrick Mallery was the first person
to record and examine Chumash rock art sites; he looked at two sites
near Santa Barbara.
The first set of samples analyzed was from a group of seven
black pigment cakes collected from excavations of Chumash Indian sites
in the nineteenth century. The pigment cakes submitted for analysis were
obtained from the American Museum of Natural History, New York
( Scott 1 9 94). The pigments had been prepared by mixing them with a
binder; the mixture was then formed into small cakes for convenience.
Harrington describes the black paints as being prepared from soot mixed
with deer marrow and made into a dough (Harrington 1 942 ) .
A n additional sample came from the Painted Rock site near
Santa Barbara, which is often described as one of the most important
Chumash pictograph sites. The site is in the Carrizo Plain area near Soda
Lake, a stopping point for migratory birds, and is adj acent to large
forests of Digger pines, both sources of food for the Chumash.
Historically, it was also home to considerable populations of deer and
antelope. By comparing the images currently at the site to historic pho
tographs, Grant showed that the site has suffered from extensive exfolia
tion and vandalism-including graffiti, gunshot damage, and modern
paint ( Grant 1 99 3 ; Scott and Hyder 1 99 3 ) . The sample, possibly paint,
was obtained from a black deposit in a painted region along a vertical
crevice in the rock; the black material has previously been described as a
tarry organic deposit, as bird droppings, or as a natural vein in the rock.
142
Chapter
6
Analysis questions
Sample set 1 . What are the binders in the seven samples cakes? Are
they the same ?
Sample 2. Does this sample contain any organic materials
that may correspond to a paint binder ?
Method
IR microanalysis was used for the first set of samples because of conve
nience, availability, and potential for use of selective solvent-extraction
techniques. Additionally, while sufficient sample was available, it was
important to retain as much sample as possible for future analytical stud
ies. IR microanalysis was required for the second sample because of the
minimal sample size-it contained only a few, barely visible black particles.
Analysis
The instrument parameters and analysis conditions were the same as
those specified in Case Study 1 .
Results-sample set 1
Of the seven paint cakes, the IR spectra showed that two clearly con
tained proteinaceous binders, while the other five appeared to contain
oil-and-resin binders. As an example, the IR spectrum for paint cake
sample T 1 74 8 2 is shown in Figure 6 . 6 , along with a reference spectrum
for dried blood of unspecified origin. Proteins are readily recognizable by
a distinct pair of absorption bands for secondary ami des that occur near
1 650 and 1 5 50 cm- t • The presence of protein is confirmed by the sharp,
triangular N-H stretching band near 3 3 5 0 cm- t . While the sample spec
trum corresponds well to the reference spectrum of blood, IR analysis
cannot differentiate between various proteinaceous media, such as blood,
gelatin, or albumin. The similarity in the two spectra, with the exception
of the hydrocarbon stretches at 2 8 00-3 000 cm- I , indicates that the pro
tein is the primary IR absorbing compound present in the sample. The
hydrocarbon stretches imply that there may be a small amount of fat or
oil present in the sample. However, within the detection limit of the
method, no indications were found that the sample contains resinous or
bituminous compounds. This finding was further confirmed by a negative
result for the extraction of chloroform and ethyl acetate-soluble compo
nents. Additionally, no water-soluble components were found in the
sample, indicating that the protein is probably not a gelatin (glue ) .
Resolution-sample set 1
Based on the IR analysis that classified sample T 1 7482 as a protein, GC
was used to identify the specific concentrations of amino acids. The GC
results showed that the ratio of amino acids present was in close agree
ment with a reference standard for blood of unspecified origin ( Scott et al.
1 99 6 ) . Now that the binder in the sample was identified as blood, there
was great interest in the source animal species. Thus, Scott submitted
the sample for immunological analysis. Using crossover electrophoresis,
Newman found positive reactions for both pronghorn antelope antiserum
143
Case Studies
Pigment cake
sample
Q)()c:UJro
�if!c:
ro
t::
E
Blood (dried)
Figu re 6.6
I R transmittance spectra for a C h u mash
I n dian pigment cake sample (T17482)
along with a reference spectrum of dried
blood of un known origi n .
4000
3500
3000
2500
2000
1 750
1 500
1 250
1000
750
Wavenumber (cm- 1 )
and for human antiserum (Newman 1 994). Thus, this example shows the
analysis sequence from a general determination to a very specific one.
Results-sample 2
In the second case, the bulk sample of the black deposit material from
the Painted Rock site was analyzed first, followed by an ethyl acetate
extraction of the sample. The IR spectra for the bulk sample and the
extraction of the sample are shown in Figure 6.7. Solvent extraction was
used selectively to remove components present in this mixture of materi
als. The spectrum for the bulk sample indicates that it contains some sili
cates and possibly carbohydrates. The ethyl acetate extraction of the
sample revealed that one component of the paint sample is an esterified
hydrocarbon (i.e., oils and fats ). Thus, historical references were checked
for the use of oil as a binder in rock art paintings.
The oil and pulp of the seed of the wild cucumber (Marah
macro carpus) has been cited as one type of binder in California rock art
(Bishop 1 994; Watchman 1 99 3 ) . This plant, commonly found in southern
California, was also used ritualistically as a body paint in a Chumash
curing procedure (Walker and Hudson 1 99 3 ) . The pulp of the cucumber
seed contains a mixture of components, primarily oils, proteins, and car
bohydrates. The oil pressed from the seeds produced a spectrum that cor
responds well with other plant oils and is primarily composed of
long-chain hydrocarbon fatty acid esters.
Other natural sources of oils or fats, such as deer fat, black
walnut oil, or pinon oil, were also native to the region. Thus, for com
parison, a sample of mule deer fat was obtained. Mule deer fat is often
1 44
Chapter
6
Black paint
bulk sample
Q).�oc'"Ec'"(J)
Black paint
ethyl acetate extract
�
�
Figure 6.7
IR transmittance spectrum for a sample of
black paint from Painted Rock along with
4000
3000
2000
1 500
1000
the spectrum for the ethyl acetate-soluble
Wavenumber (cm- ' )
portion of the sample.
cited as another paint binder, although it was probably used for body
painting. Figure 6 . 8 shows the full IR spectra for the ethyl acetate extract
of the rock art sample, along with un aged reference samples of cucumber
oil and mule deer fat. In general, the spectra are very similar, as would
be expected for samples from the same chemical family (i.e., long-chain
hydrocarbon fatty acid esters ) .
Resolution-sample 2
IR spectra provided characterization of the major components in the
sample described as a black deposit or paint found in a crevice. Based on
its chemical functional groups, the sample was determined to contain
some silicates, possibly some carbohydrates, and a long-chain hydrocar
bon fatty acid ester. Ester compounds in this category are typically fats
and oils that may potentially have been used as paint binders. However,
before specific identification can be made of the oil in the paint sample,
further analytical studies by GC must be done.
Case Study
4:
Varnish on a desk
As in archaeology, the stratigraphy of paint and varnish layers can be a
key to the interpretation of an obj ect's treatment history. Thus, it is often
important to examine the composition of individual layers. This case
study illustrates how IR spectroscopy can be used to reveal additional
information by cross section analysis.
Background
Identification of resins used for furniture finishes is important for art
historical analysis of an artifact, as well as for an initial material survey
in restoration or conservation treatments. The materials and techniques
145
Case Studies
Painted Rock
black paint sample
ethyl acetate extract
Cucumber oil
Mule deer fat
Figure 6.8
I R transm ittance spectra for the ethyl
acetate extraction of the black paint
sample from Painted Rock, along with
reference spectra for cucumber oil and
m u le deer fat.
4000
3000
2000
1 500
1 000
Wavenumber (cm- ' )
for furniture surface treatment have, for the most part, been developed
empirically throughout the ages. Collections of old recipes provide some
insight into the chemistry of varnishes used for furniture surface treat
ment (Brachert 1 9 78-79 ). Even though the natural resins used for surface
finishes (shellac, copal, pine resins, etc . ) may be difficult to analyze
because of their complex composition, natural variability, and suscepti
bility to oxidation, IR micro spectroscopy has proved to be a good
method for the characterization of many pure natural resins used in
furniture finish recipes (Derrick 1 9 8 9 ) .
A n unusual mahogany rolltop desk with hidden drawers and
elaborate mechanical devices is in the Decorative Arts collection of the
J . Paul Getty Museum ( 72 .DA.47). The desk, although not stamped with
a maker's name, is attributed to David Roentgen and is thought to date
from around 1 78 5 . It has a highly polished finish and beautiful filigree
gilt-bronze mounts. While the finish on the desk is in good condition,
conservators questioned whether the desk had been refinished, and if so,
whether any of the former finish remained below the new layers.
146
Chapter
6
Previous IR analysis of a sample from the top surface of
the German desk had shown that it contained shellac, cellulose nitrate,
and wax. However, since this sample had been removed by scraping a
small amount of finish from the surface of the piece, in was unclear
as to whether these components had been applied as layers or as a
single mixture.
Analysis questions
Are there multiple layers in the finish? If so, what is the composition of
each layer?
Method
A new sample was collected as a cross section from the top of the shelf
near a small crack. The cross section was mounted in polyester embed
ding media, then microtomed with a glass knife to produce a thin
section. The thin section was placed directly on a BaF2 window for
photo documentation followed by IR analysis. IR microanalysis was
selected in order to obtain a clear characterization of each layer in an
intact thin section.
Analysis
The layers of the thin section were characterized by FT-IR microanalysis;
the analysis conditions were the same as those specified in Case Study 1 .
Each layer was isolated for analysis by a rectangular aperture approxi
mately 20 x 1 0 0 }lm in size.
Results
A photomicrograph of this cross section after microtoming is shown in
Figure 6 . 9 . Visually the thin section contains a bottom clear yellow area
beneath a darkened opaque layer, which then was covered with a clear
layer. The top clear layer is very brittle, and small portions from this
layer were lost during the microtoming step.
IR analysis showed that the bottom yellow layer ( Fig. 6. 1 0,
spectrum C) was shellac. Further examination of the spectrum obtained
from the middle, opaque layer ( Fig. 6 . 1 0 , spectrum B) indicated that it
contained a few additional bands not present in the spectrum from the
bottom, clearer region. Subtraction of the spectrum of the bottom, clear
region from the spectrum of the middle, opaque layer resulted in a spec
trum that corresponds to calcium carbonate ( Fig. 6 . 1 0, spectrum D ) . It is
possible that the chalk was used in the final polishing stages of the shel
lac finish and that it became embedded in the shellac. Analysis of the top
clear layer ( Fig. 6 . 1 0, spectrum A) showed that it consisted of a mixture
of shellac and cellulose nitrate. This was a common commercial water
proof varnish sold in the 1 930s and 1 940s.
Resolution
For this sample, IR microanalysis of the thin cross section showed that
the desk has been revarnished at least once with a cellulose nitrate and
1 47
Case Studies
Figure 6.9
A photomicrograph of a thin -section
sample from the Roentgen desk, embed
ded i n polyester resin and microtomed to
�'" 30)Ul1",t}'.,
a thickness of 10 jJ m .
B
Fif.Cf)ccu c
())
()
c
fl
E
Figure 6 . 1 0
I R transm ittance spectra (2000-700 c m - ' )
for t h e sample shown in Figure 6.9: top
layer (cellulose nitrate/shellac), m iddle
layer (shel lac/calcium carbonate), bottom
layer (shellac). The su btraction (spectrum
B - spectrum C) produces a spectrum
(D) with absorption bands that correspond
to calcium carbonate.
- C)
D20 0 150 (180 70
Subtraction
Wavenumber (cm- ' )
148
Chapter
6
shellac varnish that was added on top of a thick shellac layer, and that
the two layers were separated by a layer containing calcium carbonate.
Case Study
5:
Reflection versus transmission
Cross sections are typically embedded for stratigraphic examinations.
However, it is not always possible or easy to microtome thin sections
from the embedded sample for IR transmission analysis. Instead, it
would be beneficial to perform IR reflection analysis directly on the
embedded sample. This case study compares the results obtained from
both reflection and transmission IR analysis for an embedded cross
section sample.
Background
Analysis was requested on a paint cross section sample from an eighteenth
century armchair in the Bayou Bend Collection of the Museum of Fine
Arts, Houston ( Shelton 1 994 ) . This highly ornate Neoclassical armchair,
or " drawing room chair," is one of a set of eight extant armchairs attrib
uted to an unknown maker working in Philadelphia in the late 1 790s
( Sands 1 993; Brown and Shelton 1 994). The distinctive decoration of
the chair includes extensive use of applied composition ornaments and a
high-contrast, water-gilded, and white painted surface.
O bservations revealed that the water gilding on the composi
tion ornaments and frame was broadly executed with a red clay bole
bound in glue, and that a lead white pigmented paint was neatly cut in
around the gilding ( Shelton 1 99 4 ) . Previous microscopic characterization
of the binders with reactive fluorescent dyes and elemental analysis of the
pigments supported the possibility of a proteinaceous binder in the white
paint layer. Visually, the cross section sample contained a thick gesso
layer, a thin red-brown bole layer, and a layer of white cut-in paint
directly over the bole layer. Above the white layer were remnants of a
clear sealer or coating on the surface, covered with a thin layer of grime
and two layers of restoration.
Analysis questions
What is the composition of each paint layer? Can comparable results be
obtained by IR micro reflection spectroscopy of the polished cross section
and by IR transmission analysis of a microtomed thin section ?
Method
The sample, as received, was embedded in a polyester medium. It was
microtomed into a thin section for IR analysis in transmission mode.
Additionally, IR reflection analysis was done on the portion of the
sample that remained in the embedded block.
Analysis
The layers of the thin section were characterized by FT-IR transmission
microanalysis by use of the conditions specified in Case Study 1 . The
microtomed surface of the remaining embedded cross section was smooth
1 49
Case Studies
and flat. It was lightly polished, then analyzed by IR spectroscopy in
reflection mode in a stepwise linear fashion, or line scan. The sample was
placed on the motorized stage of the spectrophotometer, and an analysis
window of 40 x 80 Jlm was selected. The stage was moved 1 0 0 times in
approximately 5 Jlm increments in the x direction, in order to step the
analysis window over the sample. One spectrum was collected at each
step, such that 1 00 spectra were produced for the line scan ( Fig. 6 . 1 2 )
Results-transmission analysis
From the thin section, spectra were collected for the gesso, the bole, the
layer above the bole, and the overpaint. These are shown in Figure 6 . 1 l .
The IR analysis shows that the primary binder in the gesso and the bole
layers is a protein ( see amide I and amide II bands at 1 65 0 and 1 5 50
em-i ) . Carbonate shows up strongly in the gesso layer (to the point of
saturation, 2550, 1 8 00, 1 450 and 8 70 em- i ) and can also be seen to a
lesser extent as a component in the bole. Since the analysis aperture was
wider than the bole layer, spectra may show an overlap of components.
Thus, the carbonate seen in the bole layer could be due to the gesso
layer. The primary inorganic material in the bole layer is a clay ( silicate:
sharp bands near 3 600 cm-i and a broad, strong band at 1 05 0 em- i ) .
Oil appears to b e a component i n the layer above the bole ( the white,
cut-in paint) and in the overpaint, or restoration layers ( see the carbonyl
Layer 2-above bole
Q)
'".to:if.�'"()E
c
(f)
c
Figure 6 . 1 1
I R transmittance spectra collected for four
visually distinct layers with I R transmission
microspectroscopy on a m icrotomed thin
section of paint from an eighteenth
century chair.
4000
3000
2000
Wavenumber (cm-1)
1 500
1 000
1 50
Chapter
6
Figure 6 . 1 2
I R absorbance spectra collected from
a linear step scan using IR reflection
microspectroscopy on an embedded paint
5.000
cross section from an eighteenth-century
chair. The analysis window was 40
x «0
80 IJ m , and the step size was approxi
mately 5 IJm. As the composition of the
Q)
u
c
(1j
.0
4.000
3.000
rn
.0
sample changes, so do the corresponding
I R spectra. These relative changes for
selected bands can be plotted as a line
scan, as shown in Figure 6 . 1 3 .
I
2400
I
2200
I
2000
I
I
I
1400
1 600
1 800
Wavenumber (cm- ' )
1 200
1 000
band at 1 740 cm- I , along with strong hydrocarbon stretches at 2930 and
2 8 6 0 cm- I ) . However, caution must again be used, since the appearance
of the oil bands in the layer above the bole may be due to an overlapping
aperture with the coating or overpaint layers. The spectrum for the layer
above the bole also appears to have absorption bands that correspond to
protein and to basic lead carbonate (a broad band at 1 400 cm-I, with a
band at 3 600 cm- I ) . Previous elemental analysis had indicated that lead
based pigments were found in this region. The overpaint layer contains
primarily barium sulfate (a band near 1 1 40 cm- I with three tips and a
sharp band at 3550 cm- I ) .
Results-reflection analysis
From the spectra collected in reflection mode ( Fig. 6 . 1 2 ) , line plots were
drawn that show the absorbance intensity of a particular absorption
band versus its position in the sample ( Fig. 6 . 1 3 ) . The absorbance inten
sity of a band corresponds to its relative concentration. All spectra were
collected on the same sample, so the relative height of a band from one
position can be compared to its height at another position. Since the
analysis aperture was fairly large, there are no well-defined edges for the
beginning and end of each layer. However, the peak maxima for a mate
rial should correspond well to the center of the layer in which the mate
rial is found. Also, some voids in the surface of the sample may cause
apparent decreases in the concentration that are not, in fact, real.
Examination of Figure 6. 1 3 indicates that the band assigned
to silicate ( 1 040 cm- I , line profile 1 ) exhibits the highest concentration in
the region of the red bole. This finding corresponds to an identification
of clay in this layer. The sulfate-assigned band ( 1 143 cm-I, line profile 2 )
also absorbs strongly i n one portion of the overpaint region; this finding
corresponds to the transmission results. Since the band selected for sul
fate overlaps with the silicate absorption bands, the apparent sulfate in
the bole region is likely due to the silicate band. The line profile assigned
1 51
Case Studies
Figure 6.1 3
Line scans overlaid on a photom icrograph
of the embedded paint cross section from
an eighteenth-century chai r. The line
scans show the intensity of a selected
absorption band versus its collection
position on the sample.
to carbonate ( line profile 3 , 1 45 0 cm- 1 ) is high in the layer directly above
the bole. Also, the carbonate band intensity is variable from high to
moderate in the gesso. It is possible that the gesso contains a fairly even
distribution of carbonate ( calcite) but that the intensity of the absorption
varies due to the particles and voids encountered by the beam ( i .e., that
the variation is an artifact of the reflection analysis method ) .
Line profile 4 ( 1 65 0 cm-1 ) is assigned t o the amide I band,
which is likely due to proteins. The profile lines are Autoscaled to the
maximum intensity; thus, the strong absorption for the protein at the
bottom (right edge) of the gesso layer makes the rest of the sample
appear as if it has little protein. Gesso typically has about 1 0-20 % glue;
this proportion should correspond to a small but recognizable absorption
band, such as is seen in the transmission spectra. However, the line scans
do not clearly indicate its presence.
The carbonyl band ( line profile 5, 1 73 0 cm- 1-indicative of
oil and resin) is consistently low in the gesso and in the layer above the
bole. The carbonyl band absorption increases in the region described as
a coating on the layer above the bole. This increase could be due to a
layer containing oil or a natural resin. A slight increase in the carbonyl
intensity in the overpaint area, as opposed to the gesso region, may
indicate the presence of oil in the overpaint. This finding would corre
spond with the transmission results. The increase in the carbonyl band
intensity at both edges of the sample is probably due to the polyester
embedding media.
Resolution
Obtained through direct reflection analysis performed on the mounted
cross section, the line scans of the sample provide an effective means
for examining and reporting the results. This method also provides
some hints as to thin layers that may be present in the sample.
1 52
Chapter
6
However, without the information obtained from the initial transmis
sion spectra collected from the thin section, it would have been difficult
to interpret the information in the line scan. Thus, both are important.
Comparison of reflection versus transmission methods suggests that the
organic components of the sample-such as the proteins and oils-do
not reflect the IR beam as well as do the inorganic components.
Therefore, the transmission spectral data are a better indicator for the
binders in each of the layers.
Case Study
6:
Painting cross sections
Reflection analysis showed some potential for the examination of embed
ded cross sections in Case Study 5. However, an area scan should provide
a better visual image of the components than a linear scan. An area scan
would give a total sample depiction identifying each component versus
its location, such as is obtained with elemental mapping and, to some
extent, with fluorescent staining. An IR reflection map of the entire
sample area is illustrated in this case study.
Background
Andrea Mantegna was an Italian artist of the late fifteenth and early six
teenth centuries. Many of his paintings have the very characteristic matte
appearance of glue ( distemper) paint on a fine-quality linen support,
and they were never meant to be varnished ( Rothe 1 992 ) . The distemper
technique, called Tiichlein, was popular in the Netherlands and Germany
but had not been associated with any other Italian artist.
As part of a detailed investigation of Mantegna's techniques
by Rothe, over thirty samples from ten paintings in museums in Europe
and the United States were submitted for binding media analysis ( Rothe
1 99 1 ) . Multiple methods-FT-IR microscopy, SEM-EDS, GC/mass
spectroscopy ( GCIMS), and high performance liquid chromatography
(HPLC)-were used to characterize the components in these samples. The
primary reason for analysis was to determine the presence of glue-as
opposed to egg-in the binder; egg medium was typical for wood-panel
paintings in that time period.
One sample, from Mantegna's Adoration of the Magi (J. Paul
Getty Museum, Los Angeles ) , was selected for in-depth study by several
analysis techniques. Initial IR transmission analysis on particles removed
from each visually distinct layer indicated that protein was the primary
binder. HPLC analysis of the amino acids in the protein showed that it
contained significant amounts of hydroxyproline, thus indicating that
animal glue is present in the sample. GCIMS analysis confirmed this
finding and also noted the presence of a wax and the absence of choles
terol in the sample.
Analysis question
Can IR mapping microspectroscopy be used to identify and locate sample
components? Of particular interest is the distribution of the wax that
was identified by GCIMS.
1 53
Case Studies
Method
Initial IR transmission microanalysis was done on particles removed from
each visually discrete layer as a control. Then, computer-controlled x-y
mapping of a sample in the reflection mode was selected to characterize
the components in a sample and to detect components or layers that may
not be visually apparent in an optical microscope.
Analysis
Instrument parameters for both transmission and reflection methods were
the same as conditions specified in Case Study 1 .
For the area map, a portion of the sample, a four-layer cross
x
section, was embedded and polished, then placed in the IR spectropho
tometer, and an analysis grid of 1 0
1 5 points was selected. An array of
spectra were collected by reflection of the IR radiation off the surface of
the sample at each grid point. The effective resolution of the components
x
in the sample was determined by the size of the analysis aperture and by
the density of the grid. The size of the aperture for this analysis was 20
40 fLm. The selection of size involved a trade-off between resolution and
energy throughput. The step size was approximately 20 fLm. The overlap
of the windows in the x direction provided an effective increase in the res
olution of the components in that direction. Each spectrum was the sum of
50 scans and took approximately 1 minute for collection and processing.
Results
An array of IR spectra were collected and contour maps produced that
provide information on the concentration and location of compounds in
the sample. This procedure was done by the selection of a wavelength of
interest, such as a hydrocarbon band; then its intensity versus its position
in the grid where it was collected was plotted. A total sample contour
map was prepared by connecting lines for the band intensities of similar
value. In these plots, variations in line thickness are used to represent
changes in band intensity. The thickest lines correspond to the areas of
strongest band intensity-that is, to the highest concentration of the
material. The intensities are relative to one another, and the background
intensity may not be zero, because of other absorptions in the region. In
this particular sample, because previous extensive analyses had been
done to determine its components, the selected IR absorption band and
corresponding functional group could be related specifically to compo
nents in the sample. On other samples, it would be precarious to identify
a material based on only one IR absorption band.
Figure 6 . 1 4 shows a photomicrograph of the Mantegna
sample, and Figure 6 . 1 5 shows four IR reflectance maps. Map A is a
plot for the carbonyl band at 1 730 cm- i . The highest intensities of the
carbonyl band are due to the polyester embedding media surrounding
the sample; they provide a general indication of the area analyzed. The
absence of a carbonyl band in the region of the sample corresponds to
previous analyses, which determined that the binder did not contain egg
or oil. Map B is a plot of the intensities of the carbonate band at
1 54
Chapter
6
Figure 6.14
A photomicrograph of a painting cross
section sample from the Adoration of the
Magi by Mantegna.
1 4 1 6 cm- 1 . This map shows that the entire sample contains carbonate,
with the exception of the surrounding embedding media and a central
point in the second layer where the sample contains a large particle. Map
C plots the intensity of the band at 1 092 em-I, which may correspond to
sulfates or silicates, or to both. The highest concentration of this mate
rial ( s ) is in the third layer of the sample. Map D is a plot of the intensity
of the hydrocarbon band at 2 9 1 9 cm- 1 . The highest concentrations occur
in the ground ( bottom) layer and correspond to wax.
Resolution
With the aid of the results from IR transmission studies, many of the
Figure 6.1 5 (opposite page)
components in each layer could be identified by the IR maps. Of most
IR reflectance contour maps for painting
significance was that the wax, which was previously found in the sample
cross section sample shown i n Figure 6 . 1 4 .
by GCIMS bulk analysis, can now be designated according to its location
T h e thickest lines correspond t o the
in the sample. Two potential sources for the ground-layer wax are, first,
highest-intensity absorptions. Absorption
that it could have been included in the original mixture of components in
bands mapped are (A) a carbonyl band at
the ground layer or, second, it could have come from the wax lining.
1 73 0 cm - 1 ; the high intensities represent
However, since the IR map shows a fairly even distribution of wax
the embedding media; (8) a band assigned
throughout the lower layer, it is more likely that wax was an original
to carbonate at 1 4 1 6 cm - 1 ; this map
component in the ground layer. Additionally, there is no treatment his
shows a u n iform distribution with the
tory indicating that this painting has been relined.
exception of lower levels in one region of
the m iddle layer and the surrounding
Limitations to mapping
embedding media; (C) a band assigned to
The method of IR reflection mapping shows potential for the determina
su lfate/silicate absorptions at 1 092 cm- 1 ;
tion of materials and their locations within a cross section sample. The
this map shows a higher intensity in the
technique is complementary to elemental mapping with an electron
middle layer; and (D) a hydrocarbon band
microscope and may be done on the same sample. At this point, the IR
at 2 9 1 9 cm- 1 ; this band has the strongest
mapping method has two major limitations. The first limitation is the use
intensities in the bottom layer.
of specular reflection as an analysis method; this method requires an
1 55
Case Studies
Carbonyl band ( 1 730
cm-1 )
Carbonate band ( 1 4 1 6
cm-1 )
8709 73 0.1 ", B 870.9 37
77992562 ��3" 77995226
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7
9
0.
1
>>-�77789850.0.51 O�
778850.5
0.
7
778924 0:,] �" J 778924
7 3 9543973 9 1 40.1 40.29 40. 7406 40.85410.3 412 41 0.4159 417841964215 7 39e;;;�
�§40.1 40.2940. 7 406 40.85410.3412 41 0.4159 417841964215
5
4
3
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o 7952
c 8770995273 ��/.:§��
7E:E>- 7992061
7�>- 79920.61
778850.5
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1I
778924
7 3 9543973 9 1 40.1 40.2940. 740.6 40.85410.3 412 41 0.4159 417841964215 7 3 9�543973 9 1 40.1 40.2940. 740.6 40.85410.3 412 41 0.4159 417841964215
x
0.9
A
�
X (�m)
X (�m)
Sulfate/sil icate band ( 1 092
cm-1 )
Hydrocarbon band (29 1 9
r
�
:::: �1Ii
X (�m )
cm-1)
�.�I
X (�m)
analysis window with a minimum size of 20
20 pm, because of energy
restrictions. Specular reflection can also result in band distortions and
shifts for which it is difficult to compensate. The second limitation is that
a component cannot be reliably identified based on one IR absorption
band. Thus, additional analyses are required to supplement the map and
provide interpretation. Future computer programs should allow a map to
be created based on the selection of multiple absorption bands that can
help identify specific compounds.
Case Study
7:
Vikane
Vapor-phase depletion measurements have been commonly used to study
catalyst and pollutant reactions ( Grosjean 1 9 8 5 ) . Normally these mea-
1 56
Chapter
6
surements are made by periodic sampling of the gas in a chamber and
analysis of it by a thermal or ionic detector. In this study, IR spec
troscopy was used as an in situ detector to determine the decrease in
concentration of a gas-phase fumigant, Vikane ( sulfuryl fluoride), in the
presence of various materials.
Background
Vikane was developed by Dow Chemical Company in the 1 950s,
specifically for the control of drywood termites typically found in warm
climates, such as the southern United States (Dow Chemical Co. 1 9 8 2 ) . It
has since been widely used as a structural fumigant against a variety of
destructive pests in homes, buildings, construction materials, furnishings,
and vehicles. Studies conducted on Vikane show that it has several
advantages; they include easy dispersal into a structure, rapid penetration
into materials, formation of almost no residues, and ready dissipation
after aeration (Meikle and Stewart 1 9 62).
This study was a part of a j oint investigation by the GCI,
the Canadian Conservation Institute, and the Conservation Analytical
Laboratory of the Smithsonian Institution, to examine the extent of
interaction of Vikane with a wide variety of materials under controlled
conditions. Final studies showed minimal measurable changes in most
materials with Vikane ( Baker et al. 1 99 0 ) .
Analysis question
Can IR analysis be used to determine which materials are susceptible to
interaction with Vikane ?
Method
Vapor-phase depletion measurements can be used as a fundamental
method to determine the interaction of a solid material with a gas. The
theory of this method is that when a gas is placed in a closed chamber
with a test material, the only decrease in the gas concentration will
occur by ( 1 ) leakage or penetration through seals or gaps in the
chamber, ( 2 ) absorption or reaction with the chamber walls, and/or
( 3 ) absorption or reaction with the test substrate surface. Under con
trolled experimental conditions, the first two parameters should remain
constant from run to run. Thus, the test substrate may be varied, and
several materials may be compared for their specific absorption of and
reactivity to the gas. Since the absorptions will be proportional to the
surface area, deposition or uptake of the gas can be normalized for the
surface area of each sample, so that any real differences in sample reac
tivity may be determined.
For these experiments, the concentration of Vikane was mea
sured in situ with IR spectroscopy. This measurement was performed by
placing a substrate in an IR gas cell, out of the path of the beam ( Fig.
6 . 1 6 ) , introducing Vikane, and then monitoring the concentration of the
fumigant in the cell for several hours.
1 57
Case Studies
Analysis
IR spectra were obtained at 4 cm-I resolution on a Digilab 1 5 -E FT-IR
spectrophotometer ( see Suppliers ) e quipped with a Motorola 3200
computer and a dry nitrogen purge . A wide-range, cryogenically cooled
MeT detector was used to examine the mid-IR region from 4000 to
500 cm- I . Each spectrum represents an accumulation of 500 scans. The
computer was programmed to run automatically, collecting a spectrum
every 5 minutes for the first 5 spectra, then every 10 minutes for 2 5
spectra, then every 2 0 minutes for the remaining 2 0 spectra. F o r the
0% relative humidity ( RH ) runs, the test material was placed inside
the cell, then the cell was flushed with pure, dry nitrogen and placed in
the instrument.
A spectrum was taken of the purged cell after it was placed in
the instrument to ensure that the cell was clean; this spectrum was then
Figure 6.1 6
used as a background. Then, 2-3 ml of 1 00 % Vikane was injected into
x
An IR gas cell for depletion studies. The
the gas cell, and the automated IR collection program was initiated. The
sample is placed in the bottom of the air
test materials had an exterior dimension of 2 . 5
tight cel l , and Vikane is injected; the con
After each run, the cell was rep urged with nitrogen. A t this point and
centration of Vikane over time is then
8 hours later, spectra were taken to determine whether the test materials
mon itored by the collection of I R spectra
were desorbing Vikane.
5 . 0 cm ( 1 x 2 in. ) .
of the gas in the cell over a 1 0 hour
diameter of 5 cm. The windows in the cell
Results
The gas-phase spectrum of sulfuryl fluoride produces strong vibrational
are zinc sele nide.
bands that are well resolved at 4 cm- I . The intensity of IR absorbance
period . The cell is 10 cm long and has a
1 58
Chapter
6
bands is proportional to the concentration of that species within the lin
ear range of the detector. Comparison of several blank runs showed that
the precision of the measurements for four runs with an empty cell
( blank) taken over a period of four weeks was ±2 %. Each of the curves
is linear and horizontal and represents a relatively constant concentration
for the 12 hours .
Figure 6 . 1 7 shows depletion curves for several materials
tested at 0% RH. For the blank cell, the Vikane concentration decreases
slightly in the first hour, then remains essentially constant for the next
12 hours. Similar results were seen for metals; initial slight decreases in
concentration may be related to the additional deposition surface area in
the cell. Vikane depletion is slightly greater ( 5 % ) for the cotton sample,
but it still exhibits the same general pattern of an initial drop, then a
leveling. In comparison to the other materials that were tested, the
proteins showed drastic changes. Silk-showing a 3 7 % decrease-is an
exacerbated version of the pattern noticed with proteins.
In these experiments, samples analyzed at 0% RH were
placed in a cell that was purged with dry nitrogen. However, since the
lack of oxygen and water may inhibit some reactions with Vikane-par
ticularly the corrosion of metals-additional studies were done with dry
air humidified to 6 5 % RH (with oxygen present) .
At 6 5 % RH, the curves for each metal sample exhibited a
rapid initial drop, followed by a leveling. In each case, the curves were
lower than on the comparable graph obtained in a dry nitrogen atmos
phere ( an example for brass is shown in Fig. 6 . 1 8 ) . The depletion at 6 5 %
R H ranged from 1 5 % ( copper) t o 6 % ( aluminum and silver ) , while at
0% RH, the depletions ranged from 1 % to 3 % . The presence of moisture
or oxygen seems necessary for Vikane absorption or reaction with met
g
als. Even with the depletion of the Vikane, no corrosion or tarnishin
was visible on any of the metals after 24 hours of exposure. Interestingly,
the organic materials, such as cotton and silk, showed much less Vikane
1.10
..
____---1
1 .00 1"':::_
:-- _________________Blank
OJ
Figure 6.1 7
A plot of the
IR
absorption band of Vikane
at 1 492 cm-1 versus collection time. The
.D<{'"ococu
Cotton
0.90
0.80
th ree lines show experimental results for a
blan k cel l , a piece of cotton , and a piece
0.70
of silk. The cell containing a piece of cot
ton exh ibited a 5% decrease, and the cell
with silk showed a 3 7 % decrease i n
V i kane concentration.
Silk
______ ______ _______ ___
3
9
6
0.60 L-
o
--L --1 .l...- ---1
Time (hours)
1 59
Case Studies
r-
1 .02
1 .00
Figure 6.1 8
at 1 492 cm- 1 versus collection time. The
first run involved a sample of brass placed
in the cell with a dry nitrogen atmosphere;
there was a 2 % decrease in Vi kane con
centratio n . T h e second sample o f brass
was placed in the cell with 65 % RH. That
run showed a decrease of 8% in Vikane
H ____________
____�O�%�R�
__
.0<t:UJ0'" ---f- ---I I I I
0.98
A plot of the IR absorption band of Vikane
f-�----
Q)
u
c
_J
0.96
0.94
65% RH
--- -
0.92
0.90
2
0
concentration .
4
Time (hours)
-- - -- - -
6
-
8
10
depletion in the presence of the higher humidities and oxygen than had
been found in the nitrogen atmosphere studies.
Resolution
In summary, depletion studies showed that IR spectroscopy is a useful
tool for monitoring changes in the gaseous environment in an IR cell.
While it is not possible to determine from these experiments whether the
Vikane was reacting with the materials, the results did give useful infor
mation as to the types of conditions for which reactions are most likely.
Results also showed that humidity does have an effect on Vikane's inter
actions with materials.
Case Study
8:
Parylene
Artificial aging is used to hasten the degradation of materials. In the fol
lowing study, IR spectroscopy is used to evaluate the chemical oxidation
changes that occur as samples of Parylene are exposed to filtered UVNis
radiation.
Background
Parylene, a generic name for polymers based on para-xylylene, is a con
formal, vapor-deposited coating that was considered for use in the con
servation field in the early 1 9 80s (Humphrey 1 9 84, 1 9 8 6 ) . The polymer
has been used for the last-chance consolidation of friable, otherwise
irreparable artifacts and other objects, such as ancient pinecones and
feathers (Abbey Newsletter 1 9 8 8 ) . The polymer was found to have good
thermal stability ( Grattan and Bilz 1 9 9 1 ) .
Nowlin and coworkers have shown that an uptake of oxygen
by three types of Parylene relates to a decrease in tensile strength during
thermal oxidation studies at 120 °C to 200 °C (Nowlin, Smith, and
Cieloszyk 1 9 8 0 ) . The oxidation kinetics were obtained by both neutron
activation analysis and IR spectroscopy. Comparing these two methods,
1 60
Chapter
6
Nowlin showed that the oxygen concentrations determined by neutron
activation are directly proportional to the size of a carbonyl ( C = O )
absorption band a t 1 69 5 cm- 1 i n the I R spectra. Thus, for Parylene oxi
dation, the formation of the carbonyl band in the IR spectra coincides
with a reduction in tensile strength, while also providing specific infor
mation on chemical alterations.
An initial experiment indicated that color changes occurred
in free films of Parylene-C following exposure to a xenon light source
filtered through nominal cutoff filters of 305, 345, 3 8 5 , and 400 nm
( Hansen and Ginell 1 9 8 9 ) . Yellowing occurred progressively, with both
increasing time of exposure and wavelength minima for 500 hours expo
sure. However, since the color-change kinetics did not provide specific
information on the chemical modifications or other physical properties
(e.g., tensile strength) , IR spectroscopy was used to provide information
on the chemical degradation products in the Parylene.
Analysis questions
Can the chemical degradation products of Parylene be monitored with
IR spectroscopy ? What types of radiation exposure cause measurable
degradative changes ?
Method
Attenuated total reflectance (ATR) was chosen for this study, since it
selectively analyzes the surface of the sample that is held in optical con
tact with the crystal. Since photo oxidative degradation products are
more abundant on the surface of a film, where the oxygen supply is plen
tiful, the sensitivity of the IR measurement to deterioration is increased
by use of the surface technique.
Analysis
Parylene-C ( dichloro-para-xylylene; see Suppliers, Union Carbide Corp . )
free films ( 1 2 p m thick ) were irradiated i n a Hereaus Sun-Test chamber
equipped with a xenon arc lamp filtered to yield a simulated solar spec
trum. A water-cooled support plate in the chamber maintained the
exposure temperature at 30 °C ( ± 1
0q,
which was determined by a
thermocouple placed on a sample surface. Long-band-pass optical filters
with nominal cutoffs of 305, 345, 3 8 5, 400, and 420 nm were inserted
between the xenon lamp and the Parylene-C films to determine the wave
length threshold for photooxidation. Films were removed for IR and
color measurements at intervals during the initial 500 hour exposure.
Because the 420 nm minimum filter was excluded prior to completion of
the 500 hour exposure, a second exposure experiment was conducted
under similar conditions to 750 hours, for verification of the test results.
IR measurements were made on a Digilab 1 5 - 8 0 FT-IR spec
trophotometer ( see Suppliers) with a Harrick x4 beam condenser in the
ATR mode ( see Suppliers ) . The instrument was continually purged with
dry, CO 2 -free air from a Balston clean-air unit ( see Suppliers, Whatman,
Balston Div. ) , to eliminate any atmospheric-induced interference bands.
A cryogenically cooled MCT detector was used for maximum spectral
1 61
Case Studies
sensitivity. Each spectrum represents the accumulation of 200 scans at a
resolution of 4 cm-1.
For the ATR measurements in this study, a KRS-5 (thallium
bromoiodide) crystal was used at a 45° angle of reflection. This provides
an approximate beam penetration of 5 /-Lm. A sample ( approximately 5 x
50 mm) was cut from the film, placed on one side of the crystal, and
reproducibly pressed against the crystal surface with a torque wrench set
at 2 . 8 gm-m ( 4 oz.-in . ) . Care was taken to ensure that the surface next to
the crystal was the surface of the sample that faced the xenon lamp.
Results
Figure 6 . 1 9 shows a spectral series of Parylene-C exposed under several
cutoff filters (345, 3 8 5 , 400, 420 nm) for 750 hours, along with an unex
posed control. The main changes in the IR absorption spectra detected
during the photolysis of Parylene-C are ( 1 ) an increase in band intensities
in the carbonyl region ( 1 750-1 670 cm- 1 ) , due to the uptake of oxygen;
( 2 ) an increase in intensity of the hydroxyl absorptions (a broad band at
-r-
1 .2
)\
1 .0
345 nm filter
0.8
<D15.0«Uc(f)
0.6
(;
0.4
Figure 6 . 1 9
0.2
I R absorbance spectra for Parylene-C films
after 750 hours of simulated sunl ight
exposure with UV cutoff filters (345, 385,
400, and 420 nm), along with the spec
trum of an unexposed control. The car
bonyl band at 1 695 cm-1 is an ind icator of
ph otodegradation .
0.0
3500
2500
1 400
Wavenumber (cm- 1 )
1 000
600
1 62
Chapter
6
3400 cm- I ) , due to an increase in the number of alcohols and acids; and
( 3 ) a decrease in the hydrocarbon stretching and bending frequencies
( sharp bands at 3 1 00-2 8 00 cm- I ) , which indicates a loss of carbon
hydrogen bonds due to oxidation. Overall, this spectral series shows that
with an increasing amount of UV in the light, the quantity and number of
oxidation products increases. A closer examination of the carbonyl region
shows that the appearance and growth in the band at 1 6 95 cm- I ( shown
by the arrow in Fig. 6 . 1 9 ) is the first easily recognizable indicator of the
Parylene-C oxidation process. Nowlin and coworkers found that this
band corresponded directly to the oxygen uptake by parylenes in their
thermal degradation studies (Nowlin, Smith, and Cieloszyk 1 9 8 0 ) .
Table 6 . 1 lists the total area under the carbonyl stretching
band region from 1 720 to 1 660 cm-I for each sample in the exposure
matrix. Since the sample size was not uniform for every spectral mea
surement, the areas of the carbonyl bands were normalized to an internal
reference band. Chosen for this purpose was a small band at 1 8 8 0 cm-I
( C-H wag on the aromatic ring), because it would be a relatively stable
indicator of the amount of polymer analyzed. This was also the band
that Nowlin and coworkers used for normalization in their study
(Nowlin, Smith, and Cieloszyk 1 9 8 0 ) .
Table 6 . 1 shows that there is a corresponding increase i n the
size of the carbonyl band versus the amount of UV light received by the
sample. Additionally, there is an increase in the size of the carbonyl band
with increasing time of exposure from 0 to 750 hours. Two exceptions to
these trends occur for the 500 hour exposures of the unfiltered sample
and the 305 nm filter sample; these have lower measurements than the
sample exposed under a 345 nm filter. For the unfiltered sample, the
measurement at 500 hours is lower than the measurement at 1 5 5 hours.
These lower results are due to further degradation of the oxidation prod
ucts. The samples for both of these measurements were extremely brittle
and difficult to analyze. In fact, after the 750 hour exposure, the corre
sponding samples ( unfiltered and with a 305 nm filter) were deteriorated
to the point that they could not be analyzed.
Since the growth of the carbonyl band (presented in Table
6 . 1 ) is an early indication of the photo degradation of the polymer, it is
significant to note that the area under the carbonyl band for the sample
Table 6.1
The total area u nder the carbonyl band
Time (hr)
(integrated from 1 720 to 1 660 cm-1) for
Parylene-C samples exposed to filtered
Cutoff filter (nm)
none
305
39.8
1 2 .0
0
xenon light. Each spectrum was normal-
35'
ized with the intensity of the absorption
1 55'
band at 1 880 cm- 1 at 1 .0.
500'
750
average of 6 controls
1 81
83 . 8
91 .0
1 42
2
" Not measured.
' Exposure study
2Exposure study
345
21
(up to 500 hours).
(up to 750 hours).
5 . 42
24.8
- 0 . 78
400
420
2 .43
2 . 68
3 .08
9.17
6.71
5.41
385
==
0.49
/
277
12.1
7.61
442
34.1
8 . 74
5 . 98
1 63
Case Studies
filtered with a 420 nm filter increased with exposure time. The cutoff
filters theoretically allow zero throughput of light from wavelengths
shorter than the number on the filter (i.e., higher energies ) , while allow
ing 1 0 0 % transmission of the light at wavelengths above the filter num
ber (i.e., lower energies ) . In reality, the cutoff lines are not sharp but are,
instead, approximations. In this study, a radiometer was used to deter
mine the exact photodistribution characteristics of each filter. The spec
tral distribution obtained for the xenon lamp through the 420 nm cutoff
filter indicates that some radiation from 3 9 5 nm to 420 nm was present.
This small portion of higher-energy radiation may be responsible for the
photooxidation of the material.
Comparison of the physical changes (yellowing) with the
chemical changes ( formation of the carbonyl band in the IR spectra) indi
cated that oxidative changes in the IR spectra were apparent earlier (i.e.,
at lower radiation levels) than were the color changes. This finding was
consistent with the formation of a colorless mono benzoyl prior to the
formation of deep yellow dibenzoyl.
Resolution
This example used ATR IR spectroscopy to monitor the minor changes in
the chemical composition of Parylene-C film surfaces exposed to light.
Two significant points in this study were ( 1 ) that oxidation of Parylene-C
occurred in light filtered to the visible region, and ( 2 ) that this oxidation
was measurable prior to visual discoloration, or yellowing, of the films.
When a 400 nm cutoff filter (typically found in museum environments)
was used, a carbonyl band indicating oxidation was readily apparent
after an exposure of 1 5 5 hours. Filtering of the violet portion of the spec
trum with a wavelength minima of 420 nm still resulted in a measurable
amount of chemical change in Parylene-C.
Case Study
9:
Cellulose nitrate sculptures
IR analysis is often used to study degradation products, as well as to
examine materials during different phases of degradation. While any
analysis technique can only identify the materials currently present in
a sample, information about the materials, their history, and their cur
rent condition can sometimes be used to gain insight into the degra
dation process.
Background
Cellulose esters, the modern plastics of the early 1 900s, furnished a light
weight material that could be transformed into a myriad of shapes and
colors. Because of this versatility, the plastic found many uses in every
day products ( buttons, billiard balls, cosmetic cases) , in new products
( movie film), and in works of art ( sculptures). However, it was eventually
discovered that plastic products based on cellulose nitrate were inherently
unstable. This polymer initially undergoes a very slow, spontaneous decom
position, at normal room conditions, that can progress to faster, autocat
alytic degradation in the presence of high humidity, high temperature, or
radiation (for a detailed explanation of this chemistry, see Selwitz 1 9 8 8 ) .
UV
1 64
Chapter
6
The Museum of Modern Art (MoMA) in New York has
three early polymer sculptures created in the 1 920s by Naum Gabo and
Antoine Pevsner; the artworks exemplify the Constructivist style. These
sculptures were shown by IR spectroscopy to be composed of cellulose
nitrate. Examination showed that they exhibit varying degrees of deterio
ration and range from very good to poor in overall condition. The types
of deterioration include crazing, cracking, and discoloration of the cellu
lose nitrate, as well as corrosion of some metal components that are in
contact with the plastic. When two of the pieces began exhibiting drops
of clear-to-light-brown liquid on the surface, MoMA and the GCI began
an examination of these cellulose nitrate sculptures, in order to obtain a
better understanding of the relation between various deterioration mecha
nisms and the material composition (Derrick, Stulik and Ordonez 1 99 3 ) .
Analysis questions
What is the composition of the droplets? Are they due to cellulose nitrate
degradation ?
Method
Samples were obtained from the cellulose nitrate sculptures at MoMA
and from other collections. When possible, multiple samples were taken
from several areas of each sculpture. The samples were acquired as bro
ken fragments or removed as scrapings, cross sections, and exudates.
They were analyzed by IR microspectroscopy at the GCI and by SEM-EDS,
XRD, and optical microscopy at MoMA, to identify additives in the
polymer, as well as to identify the principal component of the plastic .
The application presented below will be limited to the IR microanalysis.
Analysis
The samples were characterized by FT-IR microanalysis; the analysis
conditions were the same as those specified in Case Study 1 .
Results
IR analysis of the liquid exudate, or " sweat, " showed that it contained
an inorganic nitrate. Elemental analysis by energy dispersive spec
troscopy showed that the exudate contained zinc. Crystals formed when
the liquid was placed in a sealed container and liquefied again upon
exposure to air. This behavior corresponds to that of reference samples
of nitrate salts-for example, calcium and zinc-which are hygroscopic
and become hydrated to form a liquid at room conditions. In cellulose
nitrate, the nitrate salts can be formed by the reaction of nitric acid (a
degradation product) with fillers, stabilizers, or colorants in the piece.
Zinc oxide was commonly used as a filler and opacifier. It also acts as a
stabilizer by rapidly consuming nitric acid to form zinc nitrate.
The samples primarily contained camphor as a plasticizing
agent, in addition to an unidentified oil. The presence of camphor was
(1/4
confirmed by isolating it from the sample. This was accomplished by
placing a tiny sample in the center of a 0.6 cm
in. ) diameter glass
1 65
Case Studies
tube 1 0 cm (4 in.) long. The area of the sample was gently heated with a
flame until droplet condensation was noted on the cooler portion of the
tube. The tube was then quickly broken open, and a droplet was trans
ferred to a BaF2 pellet for analysis by IR microspectroscopy. It was
imperative to work fast, since the camphor volatilized quickly. An alter
nate method for the analysis of a volatile liquid such as camphor would
be to place the sample in a micro liquid cell or between two salt pellets.
Figure 6.20 shows IR transmittance spectra of three samples
of cellulose nitrate: one in good condition, one in moderate condition,
and one in poor condition; also shown are spectra of the camphor
and liquid nitrate salt. Noticeable in the spectra of the more degraded
samples is the increase in the intensity of the band at 1 340 cm- I , due to
the presence of nitrate salts in the sample. There is also a corresponding
decrease in the intensity of the carbonyl band at 1 73 5 cm- I that is due
to decreasing amounts of camphor.
The rate of deterioration of cellulose nitrate is dependent on
the availability of oxygen and water and on exposure to UV radiation.
This fact makes the surface of the polymer the most vulnerable area. In
order to obtain a depth profile of the degradation, a cross section sample
obtained from broken fragments of the sculpture was analyzed. The
sample was embedded in a polyester resin and then polished to a flat, shiny
surface. IR spectra were collected in reflection mode. Figure 6.21 shows
three IR absorbance spectra in the region of 1 900- 1 5 00 cm- I ; the first was
collected at the surface of the cellulose nitrate sample, while the second
and third were collected 1 and 2 mm, respectively, deeper into the sample.
All three spectra were normalized to the height of the band at 1 650 cm-I,
which corresponds to the nitrate ester groups in the cellulose nitrate. The
spectra show that the surface of the sculpture contains cellulose nitrate
with a diminished amount of camphor ( based on carbonyl at 1 740 cm- I )
compared t o the composition a t a depth o f 2 m m into the sample.
The diminished amounts of camphor in the deteriorated areas
of the plastic can be due to sublimation. Since the deteriorated surfaces
often have cracks, more area is exposed, which may allow more camphor
to sublime. Conversely, the loss of camphor may have a degenerative
effect on the plastic. Camphor was preferred as a plasticizer because it
stabilized the cellulose nitrate as well as made it less brittle ( for more
information on cellulose nitrate, see Reilly 1 9 9 1 and Edge et al. 1 99 0 ) .
Resolution
IR microspectroscopy, along with other analysis methods, was used to
increase understanding of the various types and degrees of degradation
exhibited by each sculpture. The droplets were determined to be a
hydrated nitrate salt resulting from deterioration of cellulose nitrate.
At present, there are no established treatments for reversing some of the
degradation processes that these obj ects have undergone. Since the deteri
oration of the polymer is caused by heat, light, acid impurities, and high
humidities, preventive conservation practices may minimize further
degradation by direct control of the environment.
1 66
Chapter
6
Camphor
No evident degradation
CD::=()c'""'c'"
t!=ifE
Slight yellowing
Very yellow and brittle
Figure 6.20
IR transmittance spectra for camphor (top)
Liquid n itrate salt
and a liquid nitrate salt (bottom) , along
with spectra for three samples of cellulose
n itrate (plasticized with camphor) that
visually exhibit varyi n g degrees of
3998
3332
2666
2000
1 741
1 482
1 223
964
705
Wavenumber (cm- 1 )
degradation.
Case Study
In 1 9 8 8 the
1G0e: l
Dead Sea Scrolls
began an evaluation of the optimum storage and display
conditions for the Dead Sea Scrolls. After the determination that control
of the environment is critical to the stabilization of severely degraded
1 67
Case Studies
2
Q)
()«.QIf)o
c
ro
.Q
Figure 6 . 2 1
An expanded view of IR absorbance spec
mm inside
1 mm inside
Outside surface
tra for a cellulose nitrate cross section
sample measu red at the outer surface,
1 mm inside, and 2 mm inside. The cam
phor is depleted near the surface. The
spectra are normalized to the height of
1 800
1 750
1 700
1 650
1 600
1 550
Wavenumber (cm- 1 )
the nitrate ester band at 1 650 cm-1 .
parchment samples (Hansen 1 9 9 3 ) , several methods were used to evalu
ate the state of degradation of the scroll fragments . These included XRD,
liquid chromatography, and IR spectroscopy.
Background
The collective group of documents known as the Dead Sea Scrolls were
written on parchment, papyrus, and copper scrolls. The parchment
scrolls were prepared from the skin of sheep and goats about two thou
sand years ago. Ancient preparation techniques for parchment involved
abrasive dehairing of the skin and/or use of a vegetable matter and enzy
matic dehairing bath. After removal from the baths, the skins were
stretched tightly on a frame, and the water was removed from the skins
by scraping with a half-moon knife. When dry, the skins were smoothed
by abrasion, usually with pumice stones. Additionally, there is some evi
dence that the parchment surface was treated with small amounts of
vegetable tannage or cedar oil ( Poole and Reed 1 962 ) .
Collagen, a protein, i s the primary component o f parchment
and can be irreversibly converted to gelatin. The tropocollagen molecule
is held in a triple-helical structure by hydrogen bonds that, upon the
addition of water and/or heat, can become structurally disorganized, or
gelatinized (Weiner et al. 1 9 8 0 ) . Additionally, the protein polypeptide
chain may degrade through hydrolysis or oxidation. Collagen denatura
tion to gelatin has been characterized by IR spectrophotometry by
Brodsky-Doyle, Bendit, and Blout ( 1 975 ) ; Susi, Ard, and Carroll ( 1 97 5 ) ;
a n d Warren, Smith, a n d Tillman ( 1 96 9 ) , who have shown that the most
noticeable change in an IR spectrum during denaturation is an amide II
band position shift from 1 5 50 to 1 5 3 0 cm-1 when the collagen structure
is converted to the disordered form found in gelatin.
Analysis question
What is the state of degradation for nine Dead Sea Scroll parchment
samples? These samples consist of fragments removed from intact scrolls,
along with fragments that cannot be assigned to any specific scroll.
1 68
Chapter
6
Method
Initially ATR analysis was used to characterize the front and back surface
composition of each of the samples. Later, because it was important to
determine the depth of degradation, some of the samples were prepared as
thin sections for linear step-scan analysis by IR microspectroscopy.
Analysis
ATR IR analysis was used to examine front and back surface degradation
on nonembedded scroll fragments and for comparison to three modern
reference parchment samples. The analysis conditions for ATR measure
ments are given in Case Study 8 .
Thin sections o f the samples were characterized by FT-IR
microanalysis; the analysis conditions were the same as those specified in
Case Study 1 . A linear spectral map of the Cave IV 9A3 scroll sample
was collected with an analysis window of 20 x 1 00 !-Lm stepped across
the width of the sample in 15 !-Lm increments.
Results
The surface degradation of the samples was examined by ATR by use of
the method presented. With the use of Brodsky-Doyle's method, the results
of the ATR analysis of this set of samples compared the relative differences
in position of the amide I and II bands in the spectra to the changes in
height for the two bands ( Fig. 6.22; Brodsky-Doyle, Bendit, and Blout
1 975 ) . These changes in position and height indicate the degree of denatu
ration of the collagen to gelatin. All of the scroll samples exhibit greater
degrees of denaturation than do the modern parchment reference samples.
Examination of the spectra collected across the width of sev
eral thin sections (e.g., Fig. 6.23 ) shows that the shift in amide II band
position, in addition to the change in relative intensities of both amide I
and II bands, is localized in the exterior portions of the samples. Thus,
any denaturation and hydrolysis of the collagen is primarily in the outer
20-5 0 pm, depending on the condition of the sample. In general, the skin
side of the parchment (with a smooth upper surface) exhibited degrada
tion to a greater depth than did the flesh side (the reverse ) .
Photomicrographs presented i n Figure 6.24, taken i n normal
and cross-polarized light, show that the inorganic compounds in the
sample exist only near the edges, and that the inorganic material appears
to be embedded in the parchment rather than being j ust a surface encrus
tation. IR absorption bands corresponding to nonproteinaceous materials
or additives were found in the spectra of the surface areas of all of the
scroll samples. None were detected in the interior of the samples. Three
types of compounds-carbonates, silicates (pumice, talc, or dirt) , and
alum ( aluminum ammonium sulfate )-were found as mixtures or individ
ual components in the samples. Alum, which is used in tawing parch
ment, was found in two samples. Silicates, possibly from pumice used as
an abrasive, were found in the exterior surfaces of all the scroll pieces.
Carbonates, possibly used to fill pores or as an abrasive, were present in
large amounts in one sample and in very small or nondetectable amounts
1 69
Case Studies
1 .8
n�====================��____
e n�a�
a�
t�
t io�
____�D��
u r�
____________
,
_,
1 .6
Cave IV 9A3
Temple
�.n(f)
«
.•
o
OJ
o
c
(1j
�
1 .2
• •• •
�-
Figure 6.22
The difference i n absorption band position
Scroll fragments
Reference parchment
1 .0
(amide I: 1 650 cm- 1 ; amide I I : 1 550 cm-1)
versus the ratio of their intensities (amide
I/amide I I ) . All scroll fragments exhibited
more degradation of the collagen than did
0.8
1 00
90
Band posit ion difference (amide I
80
the reference parch ment samples.
1 10
amide II [cm- 'll
1 20
in the remaining scroll samples. There could be other nonproteinaceous
compounds, such as organic tanning agents, present in the samples in
amounts too small to be detected by IR spectroscopy.
Resolution
Microanalysis showed that the samples were nonhomogeneous and that
the spectral results varied from area to area within a sample. Thus,
2.5
2
1 .5
C
::J
OJ
o
c
(1j
.n
0.5
Figure 6.23
A linear IR absorption band spectral map
1 2.0
of the Dead Sea Scroll cross section sample
shown in Figure 6.24. The analysis win
dow was 2 0
.�o
.n«(f)
x
1 00 IJm; the step size was
1 5 IJ m . The window was stepped from the
flesh side of the parch ment (scan 1 ) to the
skin side of the parchment (scan 1 2) . The
relative i ntensities of the amide I and
amide II bands change; this change indi
cates that the su rfaces of the sample are
more denatured than are the interior.
3500
3000
2500
2000
Wavenumber (cm-1)
1 500
1 70
Chapter
6
Figure 6.24
Photomicrographs of a thin section of a
sample from a Dead Sea Scroll (cave IV
9A3) at x250. Normal illumi nation was
used for the top photo; the bottom photo
was taken in cross-polarized light.
while the results themselves were reproducible (as determined by repli
cate analysis) and were characteristic of the area analyzed, they were
not necessarily representative of the entire scroll from which the sample
was taken. However, since several samples covering a wide range of
types were analyzed, the total set of the IR results on the pieces were
exemplary of many areas on the scrolls. In addition, since some areas of
the scrolls were shown to be severely degraded, the recommended stor
age conditions should be based on the worst-that is, the most gela
tinized scroll.
1 71
Case Studies
Summary
The characterization of materials is one of the most important functions
of IR spectroscopy in the art conservation field. It is often used as the
first analytical method for classifying the maj or components in a sample
submitted for analysis . Almost any type or form of sample, except for
metals, can be analyzed. In most cases, it is necessary to remove small,
barely visible particles from the obj ect.
Examples in this chapter illustrate the potential for strati
graphic microanalysis of multilayered materials. The optimal sample
form is a thin section prepared by microtoming an embedded cross sec
tion. Also explored has been the use of IR reflection techniques for the
analysis of polished cross sections for the production of molecular maps.
Currently the reflection techniques are most useful when supplemental
analyses by other methods are available.
In addition to its use in the identification of materials, IR
spectroscopy can be used to evaluate the condition of a material and to
monitor chemical reactions. Both of these functions are significant to the
evaluation and monitoring of deterioration. IR analysis is a very practical
method for comparative studies of chemical changes in relation to time
and conditions.
Appendix
I
Selected I nfrared Spectra Collections and Digitized libraries
All instrument manufacturers sell similar collections of digitized spectral
libraries that work with their search software. However, to minimize repe
tition, only a few were selected for this appendix. Please see the Suppliers
list for the names and addresses of other instrument manufacturers.
Aldrich Library of Infrared Spectra, C. J. Pouchert, ed.
Aldrich Chemical Co., 1 0 0 1 W. St. Paul Ave . , Milwaukee, WI 5 3 2 3 3
Classical hard-copy reference of IR grating spectra for pure chemicals.
Also includes polymers, organometallics, and carboxylic acid salts.
Aldrich-Nicolet Digitized Libraries
Nicolet Instrument Corp. , 5 2 2 5 - 1 Verona Road, Madison, WI 5 3 7 1 1
Digitized versions o f the classical Aldrich collection, along with digitized
spectra for chemicals sold by Sigma Chemical. Aldrich-Nicolet collection;
Sigma-Nicolet collection.
Bio-Rad Sadder Div.-see Sadder Research Laboratories.
Coblentz Society, Inc., P.O. Box 9952, Kirkwood, MO 63 1 22
Special collection books of high-quality grating spectra contributed by
government and industrial labs. Books are edited by Clara Craver and
contain text sections with good information on sample preparation and
spectral interpretation. The Desk Book of Infrared Spectra; regulated
and major industrial chemicals; gases and vapors; halogenated hydro
carbons; plasticizers and other additives.
Galactic Industries Corp., 395 Main St., Salem, NH 03079
Search, data conversion, and data processing spectroscopic software
(Spectra Calc) ; data acquisition and processing for data generated by
spectroscopy and chromatography instruments ( Lab Calc ) ; designed to
integrate laboratory data from several types of instruments.
Infrared Data Committee of Japan (IRDC), Sanyo Shupp an Boeki Co.,
Hoyu Bldg., 8, 2-Chrome, Takaru-cho, Chuo-ku, Tokyo, Japan
Search software based on wavenumbers and intensities; possibly chang
ing to fully digitized spectra ( 1 4,000 spectra ).
Selected Infrared Spectra Collections and Digitized libraries
1 73
National Chemical Laboratory for Industry ( NCLI) collection, Japan
An integrated system with a digitized collection of electron spin reso
nance, nuclear magnetic resonance, IR, and mass spectra. This database
is available online in Japan; it is described in O. Yamamoto, K. Someno,
N. Wasada, J. Hiraishi, K. Hayamizu, K. Tanabe, T. Tamura, and M .
Yanagisawa, " An Integrated Spectral Database System including IR, MS,
proton-NMR, carbon- 1 3 -NMR, ESR, and Raman Spectra," Analytical
Sciences 4 ( 1 9 8 8 } :23 3-3 9 .
Sadder Research Laboratories, Bio-Rad Sadder Div., 3 3 1 6 Spring Garden
St., Philadelphia, PA
Search software ( IR Mentor) ; hard-copy and digitized versions of spectral
libraries ( libraries contain FT-IR and grating IR spectra ) . Condensed
phase and vapor-phase standards; adhesives and sealants; attenuated
total reflectance of polymers; coating chemicals; automobile paint chips;
commonly abused drugs; controlled pyrolysates of polymers; dyes, pig
ments, and stains; fats, waxes, and derivatives; fiber and textile chemi
cals; flame retardants; flavors and fragrances; food additives; inorganics;
lubricants; manufacturing starting materials and intermediates; minerals
and clays; monomers and polymers; organometallics; pesticides and
agricultural chemicals; petroleum chemicals; pharmaceuticals; plasticiz
ers; polymer additives; prepared and prescription drugs; priority pollu
tants; rubber chemicals; solvents; steroids; surface-active agents;
water-treatment chemicals.
Also suppliers for automobile paint chips database; Canadian
Forensic Package Library; enhanced EPA Vapor-Phase Package Library;
Georgia State Crime Lab Package Library; Merck/Sadder Library;
Hummel/Sadder Polymer Library; Sadder/Scholl Polymer Processing
Library; University Package Library of Pure Compounds.
Sprouse Scientific Systems, Inc., 1 8 0 1 Crossbeam Dr., Charlotte,
NC 282 1 7
Search software (Micro-search ), hard-copy and digitized versions o f spec
tral libraries ( libraries contain FT-IR spectra; books are edited by D. L.
Hansen ) . Polymers; Solvents (Transmission Spectra); Solvents (CIRCLE
Cell Spectra); Surface-Active Agents, Solvents: Condensed-Phase, Vapor
Phase, and Mass Spectra. In addition to these four collections, digitized
IR spectral libraries on the following topics are available: the Canada
Collection: coal, shale, and clay minerals; coatings and resins; environ
mental toxins; EPA vapor-phase (corrected); epoxy resins, curing agents,
and additives; fragrances and essential oils; fibers by IR microscope; gas
phase IR of environmental chemicals; small-molecule gases and environ
mental pollutants; general chemical compounds; Georgia State Crime Lab
forensic library; Georgia State Crime Lab automotive paint; inorganics
on KBr beam splitter; inorganics on CsI beam splitter; lubricants, addi
tives, and raw materials; minerals, U.S. Geological Survey collection;
polymers by transmission; polymers by attenuated total reflectance; poly
mer additives; general organic compounds; solvents; solvents by cylindri
cal internal reflectance; solvents, vapor-phase; surface-active agents.
1 74
Appendix I
Other Coll ections
Afremow, L.
c.,
and J . T. Vandeberg
1 9 66. High resolution spectra of inorganic pigments and extenders in the mid
infrared region from 1 5 0 0 cm-I to 200 em - I . Journal of Painting Technology
38 (495 ) : 1 69-202. ( 7 8 spectra of pigments with known composition. )
American Society for Testing Materials
1 9 69. ASTM- Wyandotte Index: Alphabetical List of Compound Names, Formulas
and References to Published Infrared Spectra; an Index to 92,000 Published Infrared
Spectra. Philadelphia: ASTM. (Previous versions: ASTM special publications
1 3 1 [ 1 962], 1 3 1 -A [ I 963].)
Association of Official Analytical Chemists
1 9 75. Infrared and Ultraviolet Spectra of Some Compounds of Pharmaceutical
Interest. Rev. ed. Washington, D.C.:' Association of Official Analytical Chemists.
Bel lamy, L. J .
1 9 75. Advances in Infrared Group Frequencies. London: Chapman and Hall.
1 9 80. The Infrared Spectra of Complex Molecules. 2d ed. London: Chapman
and Hall.
Bell anto, J . , and A. H idalgo
1 97 1 . Infrared Analysis of Essential Oils. London: Heyden and Sons.
Boldyrev, A. I .
1 9 76. Infrared Spectra of Minerals. Moscow: Nedra.
B ritish Pharmacopoeia Commission
1 9 80. Infrared Reference Spectra. ( First supplement 1 9 8 1 , second supplement 1 9 82,
third supplement 1 9 84. ) London: H.M. Stationery Office.
Cai n , D. S., and S. S. Sti m ler
1 9 67. Infrared Spectra of Plastics and Resins. Part 3. Naval Research Laboratory,
Report 65 03, Feb. 2 8. Washington, D.C.: U.S. Department of Commerce.
Carro l l , G. R., W. C. lalonde, B. D. Gaudette, S. L. Hawley, and H ubert
1 9 8 8 . A computerized database for forensic textile fibres. Journal of the Canadian
Society of Forensic Scientists 2 1 : 1 .
Chicago Society for Coating Technol ogy
1 9 80. An Infrared Spectroscopy Atlas for the Coatings Industry. Philadelphia:
Federation of Societies for Paint Technology. ( 1 433 spectra. )
Coates, J . P. , and L. C. Setti
1 9 83. Oils, Lubricants, and Petroleum Products-a Library Containing Spectra
from Fuels, Lubricants, Additives and Related Materials. Norwalk, Conn.: Perkin
Elmer Corp.
Colthup, N. B . , L. H. Daly, and S. E. Wiberley
1 9 75. Introduction to Infrared and Raman Spectroscopy. 2d ed. New York: Academic
Press. (About 600 spectra . )
Dobriner, K., E . R. Katzenell enbogen, a n d R. N . Jones
1 953. Infrared Absorption Spectra of Steroids-an Atlas. Vol. 1. New York:
Wiley-Interscience.
Dolphin, D., and A. E. Wick
1 9 77. Tabulation of Infrared Spectral Data. New York: Wiley.
E l l iott, A.
1 9 69. Infrared Spectra and Structure of Organic Long-Chain Polymers.
London: Arnold.
Selected Infrared Spectra Col lections and Digitized Libraries
1 75
Farmer, V. c . , ed.
1 974. The Infrared Spectra of Minerals. Mineralogical Society Monograph 4. Surrey,
U.K. : Adlard and Son. ( Contains detailed information on the relationship of mineral
structures to their infrared spectra.)
Fl ett, M .
1 96 9 . Characteristic Frequencies of Chemical Groups in the Infrared. New York:
American Elsevier.
Fox, R. H . , and H. I. Schuetzman
1 9 6 8 . The infrared identification of microscopic samples of man-made fibers. Journal
of Forensic Science 1 3 (3 ) : 3 97-406. ( Contains 1 3 spectra of synthetic fibers.)
Gadsen, J . A.
1 975. Infrared Spectra of Minerals and Related Inorganic Compounds. London:
Butterworth.
Gore, R. c., R. W. Hannah, S. C. Pattacini, and T. J . Porro
1 9 7 1 . Infrared and ultraviolet spectra of seventy-six pesticides. Journal of the
Association of Official Analytical Chemists 54( 5 ) : 1 028-40.
Hershenson, H . H.
1 959, 1 964. Infrared Absorption Spectra Index. New York: Academic Press. (Two
volumes cover 1 945-6 2 . )
H u mmel, D .
0., F.
and
Scholl
1 9 8 1 . Atlas of Polymer and Plastics Analysis. ( Vol. 1, Polymers: Structures and
Spectra; vol. 2, Plastics, Fibres, Rubbers, Resins; vol. 3, Additives and Processing
Aids . ) New York: Verlag Chemie International. ( O ver 7000 spectra.)
I nfrared Users' Group (lRUG)
1 99 5 . Art and Conservation Materials Infrared Spectral Library. (Vol. 1, Natural and
Synthetic Products; vol. 2, Colorants [limited distribution] . ) Marina del Rey, Calif. :
Scientific Program of the Getty Conservation Institute.
Jakes, K. A., L. R. S i bley, and R. Yerkes
1 994. A comparative collection for the study of fibres used in prehistoric textiles
from eastern North America. Journal of Archaeological Science 2 1 :641-50.
Kagarise, R. E., and L. A. Wein berger
1 954. Infrared Spectra of Plastics and Resins. Part 1 . U.S. Naval Research Lab report
#4369, Washington, D.C.: U.S. Department of Commerce.
Karcher, W. , ed.
1 98 3 , 1 9 8 8 . Spectra Atlas of Polycyclic Aromatic Compounds. Vols. 1 , 2. Boston:
Kluwer Academic Publishers.
Keller, R. J .
1 9 8 6 . The Sigma Library of FT-IR Spectra. Vols. 1 , 2 . St. Louis, Mo.: Sigma
Chemical Collection.
Langenhei m, J . H . , and C. W. Beck
1 96 8 . Catalogue of infrared spectra of fossil resins (ambers). I. North and South
America. Botanical Museum Leaflets 22( 3 ):65-120. (45 spectra.)
McCl ure, A., J. Thomson, and J. Tan nah i l l
1 96 8 . Infrared spectra o f ninety-six organic pigments. Journal o f Oil and Colour
Chemists' Association 5 1 :580.
Merck, E., ed.
1 9 8 8 . Merck IR Atlas-A Collection of FT-IR Spectra. New York: VCH Publishers.
M i l ler,
F.
A., and C. H. Wilkins
1 952. Infrared spectra and characteristic frequencies of inorganic ions. Analytical
Chemistry 24: 1253-94.
1 76
Appendix I
M i n i stry of Aviation Technical Information and Library Services
1 960. An Index of Published Infrared Spectra. Vols. 1 , 2. London: Her Majesty's
Stationery Office.
Mitzner, B. M . , E. T. Theimer, and S. K. Freeman
1 9 65. The infrared spectra of monoterpenes and related compounds. Applied
Spectroscopy 1 9 ( 6 ) : 1 69-85.
Morris, W. W.
1 973. High resolution infrared spectra of fragrance and flavor compounds. Journal of
the Association of Official Analytical Chemists 56: 1 027.
Nakamoto, K.
1 97 8 . Infrared and Raman Spectra of Inorganic and Coordination Compounds. 3d
ed. New York: John Wiley and Sons.
Nyquist, R. A., and R. O. Kagel
1 9 7 1 . Infrared Spectra of Inorganic Compounds. New York: Academic Press.
( 8 92 spectra. )
Plyusni na, I. I .
1 9 77. Infrared Spectra of Minerals. Moscow: Izd. Mosk. Univ.
Polchlopek, S. E., and R. L. Harris
1 963. ATR Spectra of Surface Coatings. Stamford, Conn.: Barnes Engineering Co.
Pouchert, C. J . , ed .
1 9 8 1 . The Aldrich Library of Infrared Spectra. 3d ed. Milwaukee, Wis.: Aldrich
Chemical Co. (About 1 1 ,000 spectra. )
1 9 85-89. The Aldrich Library of FT-IR Spectra. (Vol. 1, 1 9 8 5 ; vol. 2, 1 9 8 8 ; vol. 3,
1 9 8 9 . ) Milwaukee, Wis.: Aldrich Chemical Co.
Price, B . , and J. Carlson
Forthcoming. Infrared Spectra of Naturally Occurring Minerals. Newark, N.].:
University of Delaware.
Rouen, R. A., and V. C. Reeve
1 9 70. A comparison and evaluation of techniques for identification of
synthetic fibers. Journal of Forensic Science 1 5( 3 ) :4 1 0-32. ( Contains 20
spectra of synthetic fibers.)
Siesler, H . W., and K. Holland-Moritz
1 9 80. Infrared and Raman Spectroscopy of Polymers. New York: Marcel Dekker.
Snodgrass, A . , and B. Price
1 993. Infrared Spectra of the Gettens Collection. Cambridge, Mass.: Harvard Art
Museums.
Sti m ler, S. S . , and R. E. Kagarise
1 966. Infrared Spectra of Plastics and Resins 2: Materials Developed since 1 954. U.S.
Naval Research Lab, #6392, Washington, D.C. : U.S. Department of Commerce.
Szymanski, H. A., and R. E. Erickson
1 970. Infrared Band Handbook. Rev. 2d ed. ( 2 vols. ). New York: Plenum.
Thermodynamics Research Center Hydrocarbon Project
1 9 90. Selected Infrared Spectral Data. College Station, Tex. : Thermodynamics
Research Center, Texas Agricultural and Mechanical University.
Thompson, B .
1 9 74. Hazardous Gases and Vapors: Infrared Spectra and Physical Constants.
Technical Report no. 595 (August). Fullerton, Calif.: Beckman Instruments.
Tipson, R. S .
1 96 8 . Infrared Spectroscopy of Carbohydrates. Washington, D.C.: National Bureau
of Standards.
Selected Infrared Spectra Collections and Digitized Libraries
1 77
Tungol, M. W., E. G. Bartick, and A. Montaser
1 990a. The development of a spectral data base for the identification of fibers by
infrared microscopy. Applied Spectroscopy 44(4):543-49. (Describes the development
of a reference library for polymer fibers . )
1 9 90b. Spectral data base for fibers by infrared microscopy. Spectrochimica Acta
46B: 1 535E.
Van der Marel, H . W., and H . Beutelspacher
1 976. Atlas of Infrared Spectroscopy of Clay Minerals and Their Admixtures. New
York: Elsevier.
Welti, D .
1 9 70. Infrared Vapour Spectra. New York: Heyden and Sons.
Wenni nger, J . A., and R. L. Yates
1 967. High resolution infrared spectra of some naturally occurring sesquiterpene
hydrocarbons, part 1. Journal of the Association of Official Analytical Chemists
50 ( 6 ) : 1 3 1 3-45.
1 9 70. High resolution infrared spectra of some naturally occurring sesquiterpene
hydrocarbons, 2: Second series. Journal of the Association of Official Analytical
Chemists 5 3 ( 5 ) : 949-6 1 .
White, R. G .
1 964. Handbook of Industrial Infrared Analysis. New York: Plenum Press.
Wilks, P. A., and M. R. Iszard
1 964. The Identification of Fibers and Fabrics by Internal Reflection Spectroscopy.
Presented at the 1 5th Mid-America Spectroscopy Symposium, Chicago. South
Norwalk, Conn.: Wilks Scientific Corp. ( Contains 47 spectra of fiber s . )
Yamaguchi, K .
1 96 8 . Spectral Data of Natural Products. Vols. 1 , 2. New York: Elsevier.
Zeller, M. V., and M. R. Grabowski
1 9 78. A Collection of Reference Spectra for Flame Retardant Reagents. Perkin-Elmer
Infrared Bulletin no. 66. Norwalk, Conn. : Perkin-Elmer Corp. ( Contains 30 spectra of
flame retardants for fabrics. )
Zeller, M. V., and M. P. J uszli
1 9 75. Reference Spectra of Minerals. Norwalk, Conn. : Perkin-Elmer Corp.
Zeller, M. V., and S. C. Pattacini
1 9 73. The Infrared Grating Spectra of Polymers. Perkin-Elmer Infrared Applications
Study no. 1 3. Norwalk, Conn. : Perkin-Elmer Corp. ( Contains spectra for 29 polymers
along with a flowchart to aid in the identification of polymers.)
Appendix
I
Infrared Reference Spectra
An important factor for IR spectral identification is access to reference
spectra corresponding to appropriate materials. While Appendix I sup
plied numerous commercial and literature sources for spectra, this appen
dix gives a few examples of spectra for art and conservation materials,
because commercial libraries often do not include materials encountered
in cultural artifacts.
The spectra are organized by their material classifications. For
example, gelatin and casein are both classified as proteins. Materials in
the same classification have similar chemical compositions and thus
similar spectra. The spectra sheets also provide physical data about the
sample, as well as its analysis conditions. Accompanying descriptions
supply information about the material and its use in art and conserva
tion. An alphabetical listing of the materials is given below.
Alphabetical Listing of IR Reference Spectra
Acryloid B-72, p. 1 9 1
Linseed stand oil, p. 1 8 5
Barium sulfate, p. 1 9 6
Madder, p. 200
Beeswax, crude, p. 1 84
Malachite, p . 1 99
BEVA 3 7 1 , p. 1 92
Mastic, p. 1 8 9
Carnauba wax, p. 1 8 4
Microcrystalline wax, p . 1 8 3
Casein, p. 1 82
Phthalocyanine blue, p. 1 97
Cellulose nitrate, p. 1 90
Pine resin, p. 1 8 7
Chalk, p. 1 94
Plaster, p . 1 95
Copal, Manila, p. 1 8 7
Poly( vinyl acetate ) (PVAC), p. 1 92
Dammar, p . 1 8 8
Polyamide, p. 1 93
Dragon's blood, p . 200
Polycyclohexanone, p. 1 93
Egg yolk, hen, p. 1 8 3
Polyester 1 2 F, p. 1 9 1
Elemi, p. 1 8 8
Poppyseed oil, p . 1 8 5
Gelatin, p . 1 82
Prussian blue, p. 1 9 8
Gum arabic, p. 1 79
Rice starch, p. 1 8 0
Gum tragacanth, p. 1 79
Rosin, p. 1 8 6
Gypsum, p. 1 94
Sandarac, p . 1 8 9
Hide glue, p. 1 8 1
Shellac, p . 1 90
Honey, clover, p . 1 8 0
Silica, p. 1 96
Indigo, natural, p. 1 9 7
Ultramarine, p. 1 9 8
Isinglass, p. 1 8 1
Verdigris, p . 1 9 9
Kaolin, p . 1 95
Walnut oil, p . 1 8 6
1 79
I n frared Reference Spectra
G u m Arabic
G u m Arabic
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Los Angeles County Museum of Art;
RBG, 66.1 848
Sudan
Amber color, transparent, chunks
3600-3200 cm"
3000-2800 cm '
O-H
C-H
stretching band
stretching bands
1 650 cm"
O-H
bending band
1 480-1300 cm"
1 300-900 cm"
C-H
COO
bending band
stretching bands
Gum arabic is the most commonly used gum in preparation of paints. It is a
dried, amorphous exudate from the stem of several species of Acacia trees
(Acacia senegal) in tropical and subtropical areas of the world. Most of the
current output of gum arabic is from the sub-Sahara region in Africa. The gum
is sold in the form of colorless, round lumps, as granules, as thin flakes, or as a
powder; all of these may be white or slightly yellowish. Gum arabic is
completely soluble in hot and cold water, yielding a viscous solution. It is
insoluble in alcohol. Gum arabic is used in watercolor, paints, and inks and
for textile sizing. The earliest known inks consisted of gum arabic and lamp
black.
SYNONYMS: Kordofan, picked turkey, white Sennar, Senegal gum, Ghezineh
gum, gomme blonde, gomme blanche, gum acacia, East India gum, kami.
IR ANALYSIS LAB
Loyola Marymount University, 7/6/89
IR ANALYSIS CONDITIONS
poE 1 700
=
1 20
= 4000-700 cm-'
Microscope
Cast from solvent on BaF,
Resolution 4 cm-'
Scans
Range
600 40
2000
40
=
Gum Arabic
G u m Tragacanth
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
/
G u m Sugar
(Astragalus gummifer)
Los Angeles County Museum of Art;
RBG , 66. 1 848
Western Persia
Brown, opaque, sheets
3600-3200 cm '
O-H
3000-2800 cm"
C-H
1 750-1 600 cm"
c=o
stretching band
stretching bands
Gum Tragacanth
Gum tragacanth is an exudate from several species of shrubs of the genus
Astragalus found in the dry regions of Iran, Syria, and Turkey. It is available in
the form of dull white, translucent plates or as a yellowish powder. It is
insoluble in alcohol but soluble i n alkaline solutions and solutions of hydrogen
peroxide. A soluble fraction, tragacanthin, dissolves when added to water,
whereas an insoluble fraction, bassorin (60-70% by wt.) swells to a gel-like
state. A solution is prepared by wetting the powder with alcohol, then adding
water and shaking. Gum tragacanth is used for textile sizing and printing,
pastel crayon production, leather curing, and furniture polishes.
SYNONYMS: Gum tragacanth, gum dragon, gomme adragante, Smyrna
tragacanth, Anatolian tragacanth, Persian tragacanth.
stretching band
1 650 cm"
O-H
bending band
1 480-1300 cm"
C-H
bending bands
1 300-900 cm"
COO
stretching bands
IR ANALYSIS LAB
Loyola Marymount University,
7/1 1/89
IR ANALYSIS CONDITIONS
poE 1 700
Microscope
= 1 20
Range = 4000-700 cm-'
Cast from solvent on BaF,
Resolution
Scans
40
Gum Tragacanth
2000
=
4 cm-'
60 40
/
G u m Sugar
1 80
Appendix I I
Rice Starch
Starch
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
U.S. Customs Lab, Long Beach,
Calif.
Unknown
White, opaque, powder
3600-3200 cm"
O-H
stretching band
3000-2800 cm"
1 650 cm"
C-H
stretching bands
1 480-1300 cm"
1 300-900 cm"
O-H
bending band
C-H
C-O
bending bands
stretching bands
Starches occur as granules of varying size in the rools, bulbs, and seeds of
mosl planls. Chemically, starch is a carbohydrate in the same family as
cellulose, gums, and sugars. Starch contains about 20% of water soluble
amylose and 80% of a water-insoluble fraction called amylopectin. Both
fractions correspond to different carbohydrates of high molecular weight and
formula (C,H"O,)o' Starch turns iodine blue. Starch is a fairly poor adhesive but
has been used in some cases for lining paintings. As a paint binder, it was
most popular for fingerpaints and cheap house paints.
VARIETIES: Wheat, corn, rice, dextrin, dextran, British gum, mucilage,
sorghum, potato, tapioca, arrowroot, sago palm.
IR ANALYSIS LAB
Getty Conservation Institute,
1/19/93
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
= 4 cm-'
= 200
= 4000-800 cm-'
Microscope
Bulk sample on BaF,
Resolution
Scans
Range
80 60 40
40
/
Starch
G u m Sugar
Honey, Clover
Honey
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
J.
Paul Getty Museum Antiquities
Conservation
USA
A sweet, viscous fluid produced b y bees from the nectar of flowers. Honey i s a
mixture of fructose, glucose, dextrose, and water (-20%), with trace amounts of
enzymes and oils. Its composition varies slightly depending on the source of
nectar. Honey was used since early times as a plasticizing additive to
watercolors, tempera, size, and glair.
Golden-yellow, highly viscous,
liquid
3600-3200 cm"
O-H
stretching band
3000-2800 em"
C-H
stretching bands
1650 cm"
O-H
bending band
1 480-1300 cm"
C-H
bending bands
1 300-900 cm"
C-O
stretching bands
IR ANALYSIS LAB
Getty Conservation Institute,
9/21/84
IR ANALYSIS CONDITIONS
Digilab I SE/80
= 4 cm-'
= 200
Range = 4000-800 cm-'
KBr pellet
Ground with KBr
Resolution
Scans
40 360
Honey
20 180 160 140 120 10 80 60 40
/
G u m Sugar
1 81
Infrared Reference Spectra
Hide Glue
(pearls)
Animal Glue
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
J. &
Paul Getty Museum Decoralive
Arts Conservation; Gieck Co.
USA
Ughl amber, Iranslucent, chunks
3400-3200 cm·'
N-H
31 00-2800 cm·'
1 660-1 600 cm·'
C-H stretching bands
C=O stretching band
stretching band
1 565-1 500 em·'
C-N-H
1 480-1300 cm·'
C-H
bending band
bending band
Animal glue is an adhesive consisting primarily of gelatin and other protein
residues of collagen, keratin, or elastin. Glues may be made from bones,
skins, hides, and intestines of animals (fish, goats, sheep, cattle, horses, etc.).
These agglutinating materials are removed by extraction with hot water, then
cooled and dried to produce gelatin or glue. Animal glues are available in the
form of sheets, droplets, chips, granules, cubes, and powder. They occur in a
wide variety of colors ranging from transparent to opaque and white to brown.
Glue is soaked in cool water to form a turbid jelly that will become clear and
thinner upon heating to 40 'C. Glue will decompose and darken when it is
boiled. Animal glues are strong adhesives that have been used in furniture
manufacture, gilding, gessoes, and paint binders.
VARIETIES: Animal glue, glue, gelatin, size, isinglass, fish glue, rabbit-skin
glue, bone glue, hide glue, parchment glue, calfskin glue, skin glue, Nikawa,
sturgeon glue, sturgeon's glue, deerskin glue.
IR ANALYSIS LAB
Getty Conservation Institute, 9/1 4/84
IR ANALYSIS CONDITIONS
Digilab 1 5 E/80
KBr pellet
= 4 cm-'
Ground with KBr
= 4000-£00 cm-'
Resolution
Scans = 200
Range
40 360 320 280 240 2000 180 160 140 120 10 80 60 40
Animal Glue
Isinglass
Protein
(sheets)
Fish Glue
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Zecchi
Russia
White, opaque, sheets
3400-3200 cm·'
N-H
stretching band
31 00-2800 cm·'
C-H
stretching bands
1 660-1600 cm·'
C=O stretching band
1 565-1500 cm·'
C-N-H bending band
C-H bending band
1 480-1300 cm·'
Fish glue is made from unsorted fish waste and is an adhesive consisting
primarily of gelatin and other protein residues of collagen, keratin, or elastin.
These agglutinating agents are removed by extraction with hot water, then
cooled and dried to produce gelatin or glue. Varied production techniques can
produce poor-quality fish glue. The highest quality is made from the bladders
of sturgeons. It is clear, bluish white, and very flexible. It is solidified into flat
disks that are usually broken into smaller bits for sale. Isinglass is a particularly
fine glue made from a specific type of sturgeon. It is generally sold in narrow,
soft, translucent strips. Isinglass is very expensive. Glue is to be soaked in
cool water to form a turbid jelly that will become clear and thinner upon heating
to 40'C. Glue will decompose and darken when it is boiled. High-quality fish
glues are used for paintings and gilding.
VARIETIES: Gelatin, size, isinglass, fish glue, sturgeon glue, sturgeon's glue,
ichthycoll.
IR ANALYSIS LAB
Getty Conservation Institute, 1 /28/94
IR ANALYSIS CONDITIONS
Spectra-Tech IR!!S
=
Microscope
Bulk sample on BaF,
4 cm-'
Resolution
Scans = 50
Range = 4000-700 cm-'
40 360 320 280 240 20 180
Fish Glue
10 80 60 40
Protei n
1 82
Appendix II
Gelatin
Gelatin
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Knox Gelatine, Inc.
USA
Light yellow or white, opaque,
powder
3400-3200 cm"
N-H
31 00-2800 cm"
C-H
1 660-1600 cm"
1 565-1 500 cm"
C�O stretching band
C-N-H bending band
1 480-1300 cm"
C-H
stretching band
stretching bands
Gelatin is a mixture of proteins prepared by hydrolyzing, via boiling, collagen
obtained from skin, ligaments, and tendons. Its production differs from that of
animal glue in that raw materials are selected, cleaned, and treated with
special care, so that the product is cleaner and purer than glue. Gelatin is
strongly hydrophilic and can absorb up to ten times its weight of water. It is
sold as colorless sheets or as a fine powder and is more elastic than most
animal glues. Gelatin is used for photographic film emulsions, sizing,
adhesive, ink, encapsulation, and food products.
SYNONYMS: Gelatin, gelatine, size.
bendi ng band
IR ANALYSIS LAB
Getty Conservation Institute, 1 /28/94
IR ANALYSIS CONDITIONS
Spectra-Tech IR!,S
Microscope
� 50
Bulk sample on BaF,
Resolution � 4 cm-'
Scans
Range � 4000-700 cm-'
4000 360 320 280 240 20 180
&
60 40
Gelatin
Protein
Casein
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Harvard Art Museums;
Eimer Amend
USA
Light beige, opaque, powder
N-H
stretching band
3 1 00-2800 cm"
C-H
stretching bands
1 660-1600 cm"
C�O stretching band
1 565-1500 em"
1 480-1300 cm"
C-N-H
3400-3200 em"
C-H
Casein
Casein has been used a s a glue and binder since earliest recorded periods. It
is a proteinaceous, dried precipitate produced from milk. It contains sulfur and
phosphorus. Casein can be prepared in different ways, but it is best used
when fresh. One preparation method is to add dilute hydrochloric acid to hot
skim milk. The precipitate is then collected, washed, and dried. It is a white to
yellowish powder that is insoluble in water and alcohol but is soluble in
carbonates and other alkaline solutions. For use, casein is soaked overnight
and a weak alkali (lime, borax) is added to increase solubility. Casein provides
strong adhesion and is insoluble in water when dried.
SYNONYMS: Casein, caseinate, whey glue, Casco glue, milk acid powder,
Kasein.
bending band
bending band
IR ANALYSIS LAB
Loyola Marymount University,
1 0/4/90
IR ANALYSIS CONDITIONS
P- E 1 700
Microscope
� 1 20
� 4000-700 cm-'
Dissolved in
01
H,O, dried on BaF,
Resolution � 4 cm-'
Scans
Range
40 360 320 280 240 2000 180
Casei n
60 40
Protein
1 83
Infrared Reference Spectra
Egg Yolk, Hen
(dried fil m on glass)
Egg
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
A. Parker, Getty Conservation
Institute
USA
Yellowish , oily, powder
3400-3200 cm·'
N-H
31 00-2800 cm·'
1 750-1600 cm·'
C-H stretching bands
C=O stretching bands
stretching band
1 565-1500 cm·'
C-N-H
1 480-1300 cm·'
C-H
The whole egg, yolk, or white may be used as a lempera medium. The egg
yolk is a stable emulsion of an aqueous liquid with an oily, proteinaceous
medium Ihal dries quickly into a hard, insoluble film. It is the traditional
tempera medium and may be mixed with oil andlor resin for painting. The
white of the egg, or glair, has been used as a medium for illuminated
manuscripts. It is also used as a size for attaching gold leaf. Albumen is the
adhesive substance of egg white. As a pure film, albumen is clear, brittle, and
water soluble. Water solubility can be decreased by heating or adding tannin.
VARIETIES: Egg, yolk, whole egg, egg white, glair, egg tempera, hen, duck,
chicken, goose, pheasant, pigeon, quail, albumen, albumine.
bending band
bending band
IR ANALYSIS LAB
Loyola Marymount University,
5/1 7/89
IR ANALYSIS CONDITIONS
poE 1 700
= 4 cm-'
Microscope
Dried film on KBr
= 4000-700 cm-'
Resolution
Scans = 1 20
Range
60 40
240 20
&
Egg
Protei n
Microcrysta l l i ne Wax
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
A. F. Suter
Mineral Wax
Co.
Mineral waxes are relatively pure materials that consist of a hydrocarbon series
with little to none of the alcohols or esters found in plant waxes and beeswax.
Mineral waxes are generally obtained from the fractional distillation of shale oil,
lignite, or petroleum. They are soluble in mineral oil, chloroform, naphtha,
benzene, and ether. Mineral waxes are very stable and nonreactive. Paraffin
and microcrystalline waxes are white, translucent materials.
England
White, opaque, chunks
3000-2800 cm·'
C-H
1 480-1300 cm·'
C-H bending bands
C-H torsion bands
750-700 cm·'
VARIETIES: Mineral wax, paraffin, ozokerite, ceresin, ceresine, microcrystalline
wax, earth wax, cerin, cerosin, ozocerite.
stretching bands
IR ANALYSIS LAB
Getty Conservation Institute, 6/1 5/84
IR ANALYSIS CONDITIONS
Digilab 1 5E/80
= 4 cm-'
= 4000-600 cm-'
KBr pellet
Ground with KBr
Resolution
Scans = 200
Range
40 360 320 280 240 2000 1800 160 140 120 1000 80 60 40
M i neral Wax
Wax
1 84
Appendix II
Beeswax, Crude
Beeswax
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
A. F. Suter
&
Co.
England
Brownish yellow, opaque, chunks
3600-3200 cm"'
O-H
stretching band
3000-2800 cm"'
C-H
stretching bands
1 780-1700 cm"'
C=O stretching band
1 480-1300 cm"'
C-H
bending bands
1 300-900 cm"'
750-700 cm"'
C-O
stretching bands
C-H
torsion bands
Beeswax is produced by many species of bees; the most common is Apis
me/lifica. It is secreted from the organs on the underside of the abdomen of the
worker bees and is used in forming the cells of the honeycomb. Wax may be
obtained by melting the combs in hot water and straining to remove impurities
that may contain resins, sugars, and other plant materials. The waxes from
different localities vary considerably in color and texture and chemical
composition. The color ranges from light yellow to dark brown. The darker
varieties are often bleached by exposure to light and air or with ozone or
hydrogen peroxide. Beeswax contains about 1 0% hydrocarbons in addition to
alcohols, acids, and ester. Punic wax is refined beeswax.
VARIETIES: Beeswax, punic wax, crude beeswax, bleached beeswax, yellow
beeswax, white beeswax, virgin beeswax.
IR ANALYSIS LAB
Getty Conservation Institute, 6/1 4/84
IR ANALYSIS CONDITIONS
Digilab 1 5 E/80
= 4 cm-'
= 200
Range = 4000--600 cm-'
KBr pellet
Ground with KBr
Resolution
Scans
40 360 320 2800 240 20 180 160 140 120 10 BO 600 40
&
Beeswax
Wax
Carnauba Wax
Vegetable Wax
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
A. F. Suter
Co.
Northern Brazil
Yellow, opaque, chunks
3600-3200 cm"'
O-H
stretching band
3000-2800 cm"'
C-H
stretching bands
1 780-1 700 cm"'
C=O stretching band
1 480-1 300 cm"'
C-H
1 300-900 cm"'
C-O stretching bands
C-H torsion bands
750-700 cm"'
Vegetable waxes are low-melting mixtures of long-chain hydrocarbon
compounds found in or on plants. Their properties range widely from the soft
white of Japan wax to the hard yellow of carnauba wax to the brownish black of
bitumen wax. The hard waxes, such as carnauba, are often added to softer
waxes, such as beeswax, for stiffening. Vegetable waxes generally contain
fatty acids or alcohols along with the hydrocarbon series. Carnauba, one the
hardest waxes, is obtained from the leaves of the wax palm, Copernicia
cerifera, in Brazil.
VARIETIES: Vegetable wax, bitumen wax, montan wax, candelilla wax,
candilla wax, carnauba wax, Japan wax, rice wax, Brazil wax.
bending bands
IR ANALYSIS LAB
Getty Conservation Institute, 6/1 5/84
IR ANALYSIS CONDITIONS
Digilab 1 5 E/80
= 4 cm-'
= 200
Range = 4000--600 cm-'
KBr pellet
Ground with KBr
Resolution
Scans
40 360 320 280 240 20 180 160 140 120 10 80 60 40
Vegetable Wax
Wax
1 85
Infrared Reference Spectra
Linseed Stand Oil
Linseed Oil
PROVENANCE
Ashley's Art; Grumbacher
SOURCE
USA
Yellow, transparent, liquid
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
3600-3200 cm·'
O-H
stretching band
3000-2800 cm·'
C-H
stretching bands
1 750-1730 cm·'
C=O stretching band
1 480-1300 cm·'
C-H
bending bands
1 300-900 cm·'
C-O
stretching bands
750-700 cm·'
C-H
torsion band
Linseed oil is obtained from the seeds of the flax (Unum usitatissimum) plant. It
is the most important drying oil in artists' media. The oil is commercially
extracted from the crushed seed by hot water and steam. Cold pressing is a
less efficient method for extraction, but it produces a higher-quality artist paint.
Many types of aging, refining, and bleaching procedures have been used to
purify the oil and make it dry faster. In the past, one method to refine linseed oil
was to let it stand over time. Any mucilage or impurities settled out so that a
clarified oil was produced. Modern stand oil is prepared by steam treatment, in
the absence of oxygen, to produce a thicker and glossier oil.
VARIETI ES: Linseed oil, raw, cold-pressed, refined, stand oil, blown, bodied,
boiled, sun -refined, sun-bleached, flaxseed oil.
IR ANALYSIS LAB
Loyola Marymount University, 5/3/89
IR ANALYSIS CONDITIONS
P-E 1 700
= 4 cm-'
Microscope
Dried film on KBr
= 4000-700 cm-'
Resolution
Scans = 1 20
Range
40 360 320 280 240 20 1800 160 140 120 10 80 600 40
Linseed Oil
Oil
Poppyseed Oil
(med i u m/slow d rying)
Poppyseed Oil
PROVENANCE
SOURCE
APPEARANCE
Ashley's Art; Grumbacher
USA
Very light yellow, transparent, liquid
Poppy oil is a naturally colorless transparent oil obtained from the seed of the
opium poppy (Papaver somniferum). It comes primarily from India, Russia,
France, and Asia Minor. Poppy oil dries slower than linseed oil and yellows
less, so it was sometimes used with white pigments. It produced a soft, rubbery
paint film with a long wet-in-wet work time that was popular with Impressionist
painters. Thick layers of poppy oil paint films tend to wrinkle and crack upon
aging.
SYNONYMS: Poppyseed oil, poppy oil.
CHARACTERISTIC IR
ABSORPTION BANDS
3600-3200 cm·'
O-H
3000-2800 cm·'
C- H stretching bands
C=O stretching band
1 750-1730 cm·'
1 480-1300 cm·'
stretching band
bending bands
1 300-900 cm·'
C-H
C-O
stretching bands
750-700 cm·'
C-H
torsion band
IR ANALYSIS LAB
Loyola Marymount University,
4/26/89
IR ANALYSIS CONDITIONS
P-E 1 700
Microscope
Dried film on KBr
Resolution = 4 cm-'
Scans = 1 20
Range = 4000-700 cm-'
40 360 320 280 240 20 180 1600 1400 120 10 800 60 40
Poppyseed Oil
Oil
1 86
Appendix I I
Walnut Oil
Walnut Oil
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Spectrum Naturals
USA
Walnut oil, pressed from the seeds of a walnut tree (Juglans regia), is pale in
color and dries slower than does linseed oil. It also yellows and cracks less
than linseed oil and dries faster than poppyseed oil. Nut oil was popular in
Italy, the Netherlands, and Germany. Perhaps the reason that it has now fallen
into disuse is its high cost and its tendency to turn rancid and putrid on storage.
Slightly yellow, transparent, liquid
SYNONYMS: Walnut oil, nut oil.
3600-3200 cm·'
3000-2800 cm·'
1 750-1730 cm·'
1480-1300 cm·'
1 300-900 cm·'
750-700 cm·'
O-H stretching band
C-H stretching bands
C=O stretching band
C-H
CoO
bending bands
stretching bands
C-H
torsion band
IR ANALYSIS LAB
Loyola Marymount University,
6/28/89
IR ANALYSIS CONDITIONS
poE
1700
Microscope
4 cm-'
= 120
Range = 4000-700 cm-'
Dried film on KBr
Resolution =
Scans
40 360 3200 280 240 2000 180 160 140 120 10 80 60 40
&
Walnut Oil
Rosin
Oil
(colopho ny)
Balsam
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
A. F. Suter
Balsam is a general term used to designate the resinous exudate from
Coniferae trees. These softer resins generally contain a large amount of
Co.
England
Golden-yellow, transparent, chunks
3600-3200 cm·'
3100-2800 cm·'
1740-1640 cm·'
1650-1600 cm·'
1480-1300 cm·'
1300-900 em·'
O-H
C-H
stretching band
stretching bands
C=O stretching bands
C-C
stretching band
C-H
bending bands
CoO
stretching bands
essential oils that come from trees that grow in sandy soil near the sea.
Balsam is a soft semiliquid consisting of terpenes of resinous character. Upon
distillation, a liquid portion called turpentine and a solid residue called
colo phony, or rosin, are produced. Balsams are often used in varnishes or as
paint media; however, they deteriorate easily unless a harder resin is mixed
with them. Rosin is often used in recipes for oil varnishes.
VARIETIES: Balsam, colophony, rosin, Greek pitch, Venice turpentine,
Strasbourg turpentine, Canada balsam, copaiba balsam, pine resin, larch
balsam, larch turpentine, tolu balsam, natural balsam, oleoresin, ester gum,
Bordeaux turpentine, Burgundy pitch, Burgundy resin, gum thus, olio
d'Abezzo, Jura turpentine, copaiva balsam, silver fir turpentine.
IR ANALYSIS LAB
Getty Conservation Institute, 3/22/85
IR ANALYSIS CONDITIONS
Digilab
15E/80
0.8 mg ground with KBr
Resolution = 4 cm-'
Scans = 200
Range = 400
00 cm-'
KBr pellet
0-6
40 360 320 280 240 2000 180 160 140 120 10 80 60 400
Balsam
Natural Resin
1 87
Infrared Reference Spectra
Pine Resi n
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
(Pinus edulis, pinon)
U.S. National Park Service,
Colorado
Las Animas County, Colorado, USA
Yellow tears, sticky
3600-3200 cm"
O-H
stretching band
31 00-2800 cm"
1 740-1640 cm"
C-H
stretching bands
1 650-1 600 cm"
C-C
stretching bands
1 480-1300 cm"
C-H
bending bands
1 300-900 cm"
CoO stretching bands
C=O stretching band
Balsam
Balsam is a general term used to designate the resinous exudate from
Coniferae trees. These softer resins generally contain a large amount of
essential oils that come from trees that grow in sandy soil near the sea.
Balsam is a soft semiliquid consisting of terpenes of resinous character. Upon
distillation, a liquid portion called turpentine and a solid residue called
colophony, or rosin, are produced. Balsams are often used in varnishes or as
paint media; however, they deteriorate easily unless a harder resin is mixed
with them. The United States, France, and Spain are the largest producers of
balsams.
VARIETIES: Balsam, colophony, rosin, Greek pitch, Venice turpentine,
Strasbourg turpentine, Canada balsam, copaiba balsam, pine resin, larch
balsam, larch turpentine, tolu balsam, natural balsam, oleoresin, ester gum,
Bordeaux turpentine, Burgundy pitch, Burgundy resin, gum thus, olio
d'Abezzo, Jura turpentine, copaiva balsam, silver fir turpentine, pine resin.
IR ANALYSIS LAB
Getty Conservation Institute, 7/24/90
IR ANALYSIS CONDITIONS
Digilab 1 5EtSO
KBr micropellet
Ground with KBr
Resolution = 4 cm-'
Scans = 200
Range = 4000-600 cm-'
240 20 180 160 140 120 10 80 600 40
Balsam
Natu ral Resin
Copal, Manila
Copal
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Unknown
Light amber, opaque, chunks
31 00-2800 cm"
O-H stretching band
C-H stretching bands
1 740-1 640 cm"
C=O stretchi ng band
3600-3200 cm"
1 650-1 600 cm"
C-C
1 480-1 300 cm"
C-H
stretching band
bending bands
1 300-900 cm"
CoO
stretching bands
Copal is a term given to a large variety of hard natural resins obtained directly
from trees or as fossil resins. They have a large range of solubility and color
(from colorless to a bright yellow-brown). The hardest copal resin is Zanzibar;
Sierra Leone, kauri, and Congo are of medium hardness; Manila and Borneo
are soft copals. The oldest resins are the hardest. Copal resins may be
purchased as large lumps or small tears. Congo copal is often used in
commercial spirit varnish manufacture today. Co pal resins have also been
used as oil varnishes. They tend to darken and become insoluble with age.
VARIETIES: Zanzibar, Demerara, Benguela, Sierra Leone, Mozambique, red
Angola, white Angola, Congo, kauri, Manila, Pontianak, Madagascar, Accra,
Loango, Gaboon, bastard Angola, Borneo, Singapore, South American,
Cochin, Brazilian, Benin, swamp gum, kauri gum, bush gum, Manila nubs, old
bold Pontianak.
IR ANALYSIS LAB
Getty Conservation Institute, 1 /28/94
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
Microscope
Bulk sample on BaF,
Resolution = 4 cm-'
Scans = 50
Range = 4000-700 cm-'
60 40
Copal
Natural Res i n
1 88
Appendix I I
Dammar
Dammar
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Unknown
Beige, translucent, chunks
3600-3200 cm"
31 00-2BOO cm"
1 740-1640 cm"
1 650-1 600 cm"
O-H
C-H
stretching band
stretching bands
C=O stretching band
C-C stretching band
1 4BO-1300 cm"
C-H
bending bands
1 300-900 cm"
CoO
stretching bands
Dammar, the palest natural resin, is obtained from Dipterocarpaceae (genus
Shorea or Hopea) trees growing in Malaysia and Indonesia. The soft, viscous,
highly aromatic resin oozes readily from incisions in the bark and dries to
become transparent, brittle, odorless lumps that are sorted into the following
grades: pale (A), yellow (B), amber (C), and dust. To prepare as a varnish,
dam mar pieces are placed in a cheesecloth bag partially submersed in
turpentine. After a few hours, the dammar is dissolved and any residual
material remaining in the bag is thrown out. This produces a high-quality, clear
varnish for paintings.
SYNONYMS: Damar, Malay dammar, Mata Kuching, cat's eye dammar,
penak, gum batu, hitam, Batavian dam mar, Singapore dammar, Borneo
dam mar, Pontianak dam mar, black dam mar, Pedong, East India dam mar,
grade A Batavia, no.l Singapore, Bata gum.
IR ANALYSIS LAB
Getty Conservation Institute
IR ANALYSIS CONDITIONS
Digilab 1 5E/BO
KBr pellet
Ground with KBr
Resolution = 4 cm-'
Scans = 200
Range = 4000-600 cm-'
40 360 320 280 240 20 180 160 140 120 10 80 600 40
Dammar
Natu ral Resin
Elemi
Elemi
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Unknown
Light yellow, opaque, paste
3600-3200 cm"
O-H
stretching band
31 00-2BOO cm"
C-H
stretching bands
1 740-1 640 em"
C=O stretching band
1 650-1 600 cm"
C-C
stretching band
1 4BO-1300 cm"
C-H
bending bands
1 300-900 cm"
CoO
stretching bands
Elemi is a resin derived from trees of the family Burseraceae. Because of the
high oil content of the elemis, the term was used to describe oleoresins in the
seventeenth and eighteenth centuries. Now the term usually describes Manila
elemi, which originates in the Philippines and is gathered from Canarium
communis. This resin is extremely soft and has a very pungent odor. Elemi has
been used in varnishes, but the components responsible for its initial
malleability (mono- and sesquiterpenoids) evaporate, and it eventually
hardens. Elemi has been used in printing inks, textile coatings, paper coatings,
perfume bases, and waterproofing.
SYNONYMS: Elemi gum, Luzon, Manila elemi, Nauli elemi, Canarium.
IR ANALYSIS LAB
Getty Conservation Institute, 1 /28/94
IR ANALYSIS CONDITIONS
Spectra-Tech IR I lS
Microscope
= 4 cm-'
Bulk sample on BaF,
= 4000-700 cm-'
Resolution
Scans = 50
Range
60 40
Elemi
Natu ral Resin
1 89
Infrared Reference Spectra
Mastic
Mastic
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
A. F. Suter
&
Co.
Chios, Greece
Hard, pale yellow, tears
3600-3200 cm·'
31 00-2800 cm·'
O-H
C-H
stretching band
stretching bands
1 740-1640 cm·'
C=O stretching band
1 650-1600 cm·'
C-C
1 480-1300 cm·'
C-H
bending bands
1300-900 cm·'
CoO
stretching bands
Mastic is produced by a Pistacia lentiscus tree, which grows in southern
Europe and northern Africa. The resin collected from the island of Chios has a
reputation for highest quality. Mastic is sold commercially in small, transparent
"tears" of a pale straw color. The resin is soluble in alcohol but insoluble in
petroleum ethers. It is used as a varnish for oil paintings and as an additive in
an oil medium called megilp. As with dammar, mastic varnish is prepared by
placing the resin bits in a gauze bag suspended in solvent. Mastic varnishes
yellow and become insoluble with time.
SYNONYMS: Chios mastic, Indian mastic, khinjak, Turkish mastic, pistacia
galls, Bombay mastic.
stretching band
IR ANALYSIS LAB
Getty Conservation Institute, 1 1 /5/90
IR ANALYSIS CONDITIONS
Digilab 1 5 E/80
KBr pellet
=
Inside portion ground with KBr
4 cm-'
Resolution
Scans = 200
Range = 4000--600 cm-'
40 360 320 280 240 20 180 160 140 120 10 800 600 40
&
Mastic
Natu ral Resi n
Sandarac
Sandarac
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
A. F. Suter
Co.
Sandarac comes from Callitris quadrivalvis, a small tree that grows in northern
Africa and Australia. The resin comes in pale yellow lumps or sticks that are
hard, brittle, and powdery on the surface because of oxidation. It is soluble in
alcohol and hot turpentine and forms a hard white film that becomes darker
and redder with age. Sandarac spirit varnishes are often sold as retouching
varnishes because they dry very quickly.
Northern Africa
Hard, yellow, lumps with powdery
surface
3600-3200 cm·'
O-H
stretching band
31 00-2800 cm·'
C-H
stretching bands
1 740-1640 cm·'
C=O stretching band
C-C stretching band
1 650-1 600 cm·'
1 480-1300 cm·'
C-H
bending bands
1 300-900 cm·'
CoO
stretching bands
SYNONYMS: Sandarac, Berenice, Mogador, gum sandarac, gum juniper,
white gum, Cyprus pine, Australian pine gum.
IR ANALYSIS LAB
Getty Conservation Institute, 3/22/85
IR ANALYSIS CONDITIONS
Digilab 1 5 E/80
KBr micropellet
= 200
Ground with KBr
Resolution = 4 cm-'
Scans
Range = 4000--600 cm-'
40 360 320 280 240 20 180 160 140 120 10 80 60 40
Sandarac
Natu ral Resin
1 90
Appendix I I
Shel lac
(med i u m , flake-button)
Shellac
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
J.
Paul Getty Museum Paintings
Conservation
N/A
Amber, transparent, flakes
3600-3200 cm"
O-H
31 00-2800 cm"
C-H stretching bands
C=O stretching band
1 740-1640 cm"
stretching band
1 650-1600 cm"
C-C
1 480-1300 cm"
C-H
bending bands
1 300-900 cm"
C-O
stretching bands
Shellac is the resinous secretion of the lac insect Tachardia /acca. The insect
feeds on a plant and converts the plant juice into the resin and red dye
exudate. It comes almost entirely from India. The crude lac, seed lac, is
gathered from the trees and crushed as !lraded. The lac is then washed,
heated, and drawn into thin sheets. When cool, the sheets are broken into
fragments for sale as flake shellac. Shellac colors range from a deep red to a
pale gold. Shellac is soluble in alcohol and is used to obtain the high gloss on
French polished furniture.
VARIETIES: Shellac, baisakhi, jethwi, seed lac, stick lac, button lac, black
button lac, kiri, garnet lac, orange flakes, lemon flakes, bleached shellac,
refined shellac.
stretching band
IR ANALYSIS LAB
Getty Conservation I nstitute
IR ANALYSIS CONDITIONS
Digilab 1 5E/80
KBr pellet
= 4 cm-'
Ground with KBr
= 4000-500 cm-'
Resolution
Scans = 200
Range
240 20
Shel lac
Natural Resin
Cel lulose Nitrate
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
( 1 . 8%
N)
Lawrence Livermore Labs
USA
Colorless, transparent
3600-3200 cm"
O-H
stretching band
31 00-2800 cm"
C-H
stretching bands
1 660-1625 em"
N-O
stretching band
1 285-1 270 cm"
N-O
stretching band
1 480-1 300 cm"
1 300-900 cm"
C-H
C-O
bending bands
bending bands
890-800 cm"
N-O
bending band
Cellulose Nitrate
Some of the earliest synthetic resins were made from cellulose fibers.
Cellulose nitrate was first made as a substitute for ivory and later was used for
photographic film and as clear lacquers, adhesives, and high-gloss paints.
Celluloid is a proprietary product of cellulose nitrate mixed with camphor as a
plasticizer. Cellulose nitrate is inherently unstable and slowly decomposes at
room temperature. UV light, heat, andlor high humidities can hasten its
decomposition. Cellulose nitrate is still commercially available and is used as
adhesives and coatings.
VARIETIES: Celluloid, pyroxylin, airplane wing dope, nitrocellulose, guncotton ,
collodion, Duco, celloidin, celluidine, photoxylin.
IR ANALYSIS LAB
Getty Conservation Institute, 2/23/87
IR ANALYSIS CONDITIONS
Digilab 1 5E/80
KBr micropellet
Ground with KBr
Resolution = 4 cm-'
Scans = 200
Range = 4000-600 cm-'
40 360 320 280 240 20 180 160 140 120 10 80 60 40
Cellulose Nitrate
Synthetic Resin
1 91
I nfrared Reference Spectra
Acryloid
PROVENANCE
8-& 72:
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
methyl acrylate/ethyl methacrylate copolymer
Acrylic
Conservation Materials Ltd.; Rohm
Haas
USA
Transparent, colorless, pellets
31 00-2BOO cm·'
C-H
1 740-1640 cm·'
C=O stretching band
1 4BO-1300 cm·'
C-H
stretching bands
bending bands
1 300-900 cm·'
C-O
stretching bands
Acrylic resins are a commercially important family of polymers that were first
made in 1 901 and sold by Rohm
Haas and Du Pont in the United States
since the 1 930s. Acrylics have many popular uses. They are sold in solid form
as glass substitutes under the names of Plexiglas and Lucite; they are also
used as adhesives, varnishes, and paint media (Acryloid F- l 0, Lucite 44,
Acryloid B-72). Bocour Artists Colors began selling Magna acrylic-based artist
paints in 1 949. While the resins are generally soluble in mineral spirits and
turpentine, they may also be dispersed in water to form acrylic emulsions such
as Rhoplex AC-234. Uquitex, an acrylic emulsion paint, was first marketed in
1 954.
&
VARIETIES: Plexiglas, Lucite, Acryloid, Paraloid, Rhoplex, Uquitex.
IR ANALYSIS LAB
Getty Conservation Institute, 4/30/90
IR ANALYSIS CONDtTIONS
Digilab 1 5 E/BO
KBr pellet
Ground with KBr
Resolution = 4 cm-'
Scans = 200
Range = 4000-500 cm-'
40 3600 320 280 240 20 180 160 140 120 1000 80 60 40
Acrylic
Polyester
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Synthetic Resin
12F
Polyester
American Hoechst Corp.
USA
White, translucent, fibers
31 00-2BOO cm·'
C-H
stretching bands
1 740-1640 cm·'
C=O
stretching band
1 620-1420 cm·'
aromatic bands
1 4BO-1300 cm·'
C-H
C-O
1 300-900 cm·'
Polyester resins are a special type of alkyd resins. When catalyzed, they can
harden at room temperature and pressure with very little shrinkage to produce
a clear, colorless filament, block, or film. They are often used for encapsulating
and embedding samples and objects. One type of polyester, polyethylene
terephthalate, is used to make Mylar and other strong, moisture-resistant films,
as well as to make Dacron, an important textile fiber.
SYNONYMS: Polyester, Dacron, Mylar, Bio-Plastic, Caroplastic, Castolite,
Vestopal, Terelene, Cronar.
bending bands
stretching bands
IR ANALYSIS LAB
Getty Conservation Institute
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
Microscope
= 1 00
= 4000-700 cm-'
Bulk sample on BaF,
Resolution = 4 cm-'
Scans
Range
40 360 320 280 240 20 180 160 140 120 10 80 60 40
Polyester
Synthetic Resin
1 92
Appendix I I
Poly(vinyl acetate)(PVAC)
Poly(vinyl acetate)
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Conservation Materials Ltd_
USA
Transparent, colorless, pellets
1 750-1 650 cm·'
C-H stretching bands
C=O stretching band
1 480-1300 cm-'
C-H
1 300-900 cm·'
CoO stretching bands
C-H torsion band
3 1 00-2800 cm·'
750-700 cm·'
Poly(vinyl acetate) (PVAC) was first produced in 1 9 1 2 and was used as an
artists' medium in 1 938. Water-based emulsions, or latex, paints have been
used as house paints as well as artists' media. Vinyl polymer resins produce
clear, hard films and are also used as coatings, hot melts, and adhesives.
Other types of vinyl polymers include polyvinyl butyral, polyvinyl chloride,
polyvinylidene chloride, and polyvinyl alcohol.
VARIETIES: Poly(vinyl acetate), Vinylite, Vinylac, Elmer's glue, Vinamul,
Mowilith, AYAT.
bending bands
IR ANALYSIS LAB
Getty Conservation Institute
IR ANALYSIS CONDITIONS
Digilab 1 5 E/80
KBr pellet
Ground with KBr
Resolution = 4 cm-'
Scans = 200
Range = 4000-500 cm-'
40 360 320 280 240 20 180 160 140 120 10 80 60 40
371:
371
Poly(vi nyl acetate)
B EVA
Synthetic Resin
ethylene/vi nyl acetate copolymer mixed with polycyclohexanone
BEVA
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Australian Museum; Adam
Chemical Co.
Australia
White, opaque gel, dried to film
31 00-2800 cm·'
C-H
1 750-1 650 cm·'
C=O stretching band
stretching bands
1 480-1 300 cm·'
C-H
1 300-900 cm·'
CoO stretching bands
C-H torsion band
750-700 cm·'
BEVA 371 is a thermoplastic, elastomeric polymer mixture. It is composed of
Elvax (ethylenelvinyl acetate [EVA] copolymer), Ketone Resin N
(polycyclohexarione), A-C copolymer (EVA), Cellolyn 21 (phthalate ester of
hydroabietyl alcohol), and paraffin. It is an opaque gel at room temperature
and has a melting point of 50-55 °C. It is soluble in naphtha, toluene,
acetone, and alcohol. BEVA produces a matte, waxy finish and is used as a
consolidant for paintings and textiles.
bending bands
IR ANALYSIS LAB
Getty Conservation Institute, 4/30/90
IR ANALYSIS CONDITIONS
Digilab 1 5E/80
Attenuated total reflectance (ATR)
Free film
= 4000-500 cm-'
Resolution = 4 cm-'
Scans = 200
Range
40 360 320 280 240 20 180 160 140 120 10 80 60 40
B EVA 371
SynthetiC Resin
1 93
I nfrared Reference Spectra
Polycyclohexanone
Polycyclohexanone
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
H . Lanke
Unknown
Polycyclohexanone resins are important because they are soluble in
turpentine. This allows them to be mixed with or used instead of natural resins
as varnishes. They resemble dammar closely but are harder and remain
practically colorless. Some studies have shown, however, that solubility may
be lost over time.
White, translucent, chunks
OTHER VARIETIES: AW-2, MS2A, ketone N, BASF N, Laropal K-80.
3600-3200 cm"
O-H
stretching band
31 00-2800 cm"
C-H
stretching bands
1 750-1650 cm"
C=O stretching band
1 480-1300 cm"
C-H
bending bands
1 30D-900 cm"
C-O
stretching bands
75D-700 cm"
C-H
torsion band
IR ANALYSIS LAB
Getty Conservation Institute, 1 0/8/84
IR ANALYSIS CONDITIONS
Digilab 1 5 E/80
KBr pellet
Ground with KBr
= 4000-600 cm-'
Resolution = 4 cm-'
Scans = 200
Range
40 360 320 280 240 20 180 160 140 120 10 80 60 40
Polycyclohexanone
Synthetic Resin
Polyamide
Polyamide
PROVENANCE
SOURCE
APPEARANCE
Scientific Polymer Products, Inc.
(catalog no. 385)
USA
Polyamides can be thought of as synthetic proteins because they are made by
the polymerization of amino acids or lactams. Polyamides are thermoplastic
resins that are characterized by their high degree of toughness, strength, and
durability, along with their resistance to chemicals and heat. They are
manufactured as bristles, libers, molding powders, sutures, adhesives, and
coatings. The most important examples
polyamides are the various kinds of
nylon.
01
White, powder
VARIETIES: Nylon, Versamid, Nylon-6, soluble nylon.
CHARACTERISTIC IR
ABSORPTION BANDS
3400-3250 cm"
N-H
31 00-2800 cm"
C-H stretching bands
C=O stretching band
1 700-1630 cm"
1 620-1550 cm"
1 480-1300 cm"
N- H
C-H
stretching band
bending band
bending bands
IR ANALYSIS LAB
Getty Conservation Institute, 1 0/1/84
IR ANALYSIS CONDITIONS
Digilab 1 5 E/80
= 4 cm-'
= 200
Range = 4000-600 cm-'
KBr pellet
Ground with KBr
Resolution
Scans
40 360 320 280 240 20 180 160 140 120 10 80 60 40
Polyamide
Synthetic Resin
1 94
Appendix II
Chalk:
calcium carbonate, GaG0 3
Calcium Carbonate
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Calcium carbonate is found in many natural forms such as chalk, limestone,
marble, and seashells. It can be found worldwide and ranges in color (because
of impurities) from white to gray to yellow. The pigment is prepared by grinding
the stone or shell with water and by levigating to separate the coarser material.
Artificial chalk is known as precipitated chalk and is whiter and more
homogeneous than natural chalk. Pearl white is made from calcined oyster
shells. Calcium carbonate reacts with acids to evolve carbon dioxide.
France
White, opaque, powder
1490-1370 cm·'
910-850 cm"'
CO;O-C-O
stretching band
bending band
SYNONYMS: Calcium carbonate, chalk, pearl white, oystershell white, marble,
limestone, whiting, lime white, aragonite, calcite, marl, travertine, CI Pigment
White
18.
IR ANALYSIS LAB
Getty Conservation I nstitute,
10/15/92
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
�4
� 200
Range � 4000-800 cm-'
Microscope
Bulk sample on BaF,
cm-'
Resolution
Scans
Comment: baseline corrected
40 360 320 280 240 20 180
10 80 60 40
Calcium Carbonate
Gypsu m :
White
calciu m sulfate, dihydrate, GaS04 '2H 20
Calcium Sulfate
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Unknown
VARIETIES: Calcium sulfate, anhydrite, gypsum, plaster, terra alba, alabaster,
hydrated calcium sulfate, mineral white, stucco, Keene's cement, Martin's
cement, Mack's cement.
White, powder
1 140-1080 cm"'
-620 cm"'
3700-3200 cm·'
Calcium sulfate can be commonly found in three forms: anhydrous (anhydrite),
dihydrate (gypsum), and hemihydrate (plaster of Paris). Anhydrite is a
colorless, inert pigment that is often a component in gesso grosso, while pure
calcium sulfate dihydrate is found in gesso sottile. Gypsum is also used as a
filler and as a base for lake pigments.
asymmetric SO.'" stretching band
SO.'" bending band (not shown)
antisymmetric and symmetric O-H
stretching bands
IR ANALYSIS LAB
Getty Conservation Institute
IR ANALYSIS CONDITIONS
Digilab
15E/80
� 4 cm-'
� 200
� 4000-500 cm-'
KBr pellet
Ground with KBr
Resolution
Scans
Range
10 80 60 40
Calcium Sulfate
White
1 95
I nfrared Reference Spectra
Plaster:
calcium sulfate, hemihydrate, CaS04 °1/2H 20
Calcium Sulfate
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Germany
VARIETIES: Calcium sulfate, anhydrite, gypsum, plaster, terra alba, alabaster,
hydrated calcium sulfate, mineral white, stucco, Keene's cement, Martin's
cement, Mack's cement.
White
1 1 40-1080 cm"
Calcium sulfate can be commonly found in three forms: anhydrous (anhydrite),
dihydrate (gypsum), and hemihydrate (plaster of Paris). Anhydrite is a
colorless, inert pigment that is often a component in gesso grosso, while pure
calcium sulfate dihydrate is found in gesso sottile. Gypsum is also used as a
filler and as a base for lake pigments.
asymmetric SO." stretching band
-620 cm"
SO;- bending band (not shown)
3700-3200 cm"
antisymmetric and symmetric O- H
stretching bands
IR ANALYSIS LAB
Getty Conservation Institute,
10/15/92
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
= 4 cm-'
= 200
Range = 4000-800 cm-'
Microscope
Bulk sample on BaF,
Resolution
Scans
Comment: baseline corrected
40 360 3200 280 240 2000 180 160 140 120 10 80 600 40
Calcium Sulfate
Wh ite
Clay
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Germany
White
O-H stretching bands
3700-3200 cm"
1 1 00-1000 cm"
asymmetric Si-O-Si stretching bands
9 1 0-830 cm"
Si-O stretching bands
Many types o f clay naturally occur around t h e world. They are prinCipally
composed of hydrated aluminum silicate. Small amounts of other minerals can
change the color (white, yellow, brown, or red) and texture of the clays. Clay is
usually formed by the weathering of aluminum-bearing rocks, such as granite.
When pure, china clay (kaolin) is a fine, white, amorphous powder that
becomes very plastic when water is added. When heated to high
temperatures, clays became hard because of the loss of water and are used to
make pottery, porcelain, and bricks. Clay is also used as a filler and whiting in
paints and grounds.
VARIETIES: China clay, kaolin, modeling clay, porcelain clay, Tonerde, fuller's
earth, white bole, bolus alba, terra alba, pipe clay, Bouvigal white, Rouen
white, Spanish white, feldspar, ball clay, bentonite, stoneware clay, kaolinite,
illite, montmorillonite, halloysite, argilla.
IR ANALYSIS LAB
Getty Conservation Institute,
10/15/92
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
= 4 cm-'
= 200
Range = 4000-800 cm-'
Microscope
Bulk sample on BaF,
Resolution
Scans
Comment: baseline corrected
40 360 3200 280 2400 20 180 160 140
Clay
600 40
Wh ite
1 96
Appendix II
Silica :
Si0 2
Silica
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Silica is widely available because it makes up one of the largest portions of the
earth's crust. In its purest form, silica, or silicon dioxide, occurs as quartz. The
more common, but less pure, forms are quartzite, sandstone, and sand. The
fossil form of silica is diatomaceous earth. All forms of silica are inert,
unaffected by heat, insoluble in strong acids (except hydrofluoric), and slowly
attacked by strong alkalis. Silica is not commonly used as a pigment; however,
it is found in grounds, primers, and wood fillers. Silica is used in the
manufacture of glass, ceramics, and enamelware.
USA
White
1 1 00-1000 cm"
asymmetric Si-O-Si stretching band
VARIETIES: Silica, silicon dioxide, quartz, silex, diatomaceous earth, sand,
flint, chalcedony, opal, agate, diatomite.
IR ANALYSIS LAB
Getty Conservation Institute, 1 0/1 6/92
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
= 4 cm-'
= 200
=
Microscope
Bulk sample on BaF,
Resolution
Scans
Range 4000-800 cm-'
Comment: baseline corrected
60 40
40 360 320 280 240 20 180
Sil ica
Wh ite
Barium Sulfate :
BaS04
Barium Sulfate
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Barium white is obtained naturally from t h e mineral barite. I t c a n also b e made
artificially by a process discovered in the late nineteenth century. The
artificially prepared barium sulfate is called blanc fixe. It is a white, opaque
pigment composed of zinc sulfide and barium sulfate. The mixture of the two
components is so intimate that it is hard to distinguish microscopically. It is an
inert, transparent pigment that is often used as a filler or as a base for lake
pigments.
Germany
White
sot
1 200-1050 cm"
asymmetric
3700-3200 cm"
O-H stretching bands
stretching bands
SYNONYMS: Barium sulfate, baryte, barite, terra ponderosa, blanc fixe,
permanent white, silver white, Albilith, Becton white, Orr's white, Permalba,
baryta white, Constant white, Schwerspatweiss, heavy spar, CI Pigment White
22.
IR ANALYSIS LAB
Getty Conservation Institute, 1 0/1 5/92
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
Microscope
= 4 cm-'
= 200
Range = 4000-800 cm-'
Bulk sample on BaF,
Resolution
Scans
Comment: baseline corrected,
contains carbonate ( 1 450 cm-') and
hydrocarbon (3000-2800 cm-')
impurities
40 360 320 280 240 20 180 160 140
Bari um Sulfate
60 40
White
1 97
I nfrared Reference Spectra
Indigo
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Indigo is a natural, dark blue dye obtained from the Indigofera tinc/oria plants
native to India, Java, and other tropical areas. Synthetic indigo, first produced
in 1 880, has almost entirely replaced the natural dyestuff. The natural material
is collected as a precipitate from a fermented solution of the plant. It is a fine
powder that may be used directly as a pigment in oil, tempera, or watercolor
media, but it is more commonly used as a textile dye. The exposed material
can fade rapidly in strong sunlight.
H. Schweppe
Java
Blue, powder
3400-3200 cm"
31 00-2800 cm"
1 700-1 550 cm"
1 620-1420 cm"
N-H
C-H
c=o
stretching band
stretching bands
SYNONYMS: Indigo carmine, intense blue, indico, indican, anil, anneill, blue
ynde, CI 73000.
stretching band
aromatic bands
IR ANALYSIS LAB
Getty Conservation Institute, 4/29/93
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
Microscope
= 200
Bulk sample on BaF,
4 cm-'
==
Resolution
Scans
Range 4000-800 cm-'
Comment: baseline corrected
40 360 320 280 240 20 180 160 140 120 10 80 60 40
Indigo
Blue
Phthalocyanine Blue
(royal blue
PB1 53)
Phthalocyanine Blue
PROVENANCE
SOURCE
Kremer-Pigmente
Copper phthalocyanine (phthalocyanine blue) is a synthetic organic pigment
that was first introduced in 1 935. It is usually adsorbed on an aluminum
hydrate base to form a deep blue color. Other colors are achieved by varying
the formulation-i.e., chlorinated copper phthalocyanine produces a green
colorant. Phthalocyanine colors are important commercial pigments because
of their light and chemical stability. They are used in enamels, automotive
paints, plastics, and inks.
Germany
APPEARANCE
Blue, powder
CHARACTERISTIC IR
ABSORPTION BANDS
31 00-2800 cm"
C-H
stretching bands
1 700-1 550 cm"
C=N
stretching band
1 620-1420 cm"
aromatic bands
1 480-1300 cm"
C-H
bending bands
1 330-1 1 00 cm"
CoN
stretching bands
SYNONYMS: Heliogen blue, Monastral blue, phthalocyanine green, Winsor
blue, CI Pigment Blue 1 5.
IR ANALYSIS LAB
Getty Conservation Institute, 1 0/1 3/92
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
= 4 cm-'
Microscope
Bulk sample on BaF,
Resolution
Scans
=
200
Range = 4000-800 cm-'
Comment: baseline corrected
40 360 320 280 240 20 180 160 140 120 10 80 60 40
Phthalocyanine Blue
Blue
1 98
Appendix I I
Prussian Blue
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Germany
SYNONYMS: Prussian blue, Turnbull's blue, Paris blue, Saxon blue, Milori
blue, Chinese blue, bronze blue, Berlin blue, American blue, Antwerp blue,
steel blue, mineral blue, iron blue.
Blue
-2100 cm '
Prussian blue, synthetically produced ferric ferrocyanide, was discovered in
1 704. Its finely divided particles are a deep blue. It is transparent, has high
tinting strength, and is stable to light and high temperatures; but it turns brown
in the presence of alkalis. It is used in paints and printing inks.
[Fe(C=N),J'" ion stretching band
IR ANALYSIS LAB
Getty Conservation Institute, 1 0/1 3/92
IR ANALYSIS CONDITIONS
Spectra-Tech IRIlS
=
= 200
Range = 4000-800 cm-'
Microscope
Bulk sample on BaF,
4 cm-'
Resolution
Scans
Comment: baseline corrected
40 360 320 2800 240 2000 1800 160 140 120 1000 80 60 40
Prussian Blue
Blue
Ultramarine
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Unknown
Blue, opaque, powder
1 1 50-950 cm"
overlapping stretching bands for Si-O-Si,
2340 cm"
and Si-O-AI
sulfur ion stretching band that occurs in
some natural ultramarines
The pigment ultramarine can be prepared from a natural semiprecious stone,
lapis lazuli. The pigment is composed of silicon, aluminum, sodium, sulfur, and
oxygen. A commercial process for synthetic ultramarine, developed in the
1 820s, produces a very pure, deep, fine-particle material. Variations in the
process give a wide range of shades of blues, violets, and reds. The pigment
is stable to light but is affected by acids.
SYNONYMS: Lapis lazuli blue, lazurite, ultramarine blue, bleu d'azur,
ultramarine ash, French ultramarine, ultramarine red, ultramarine violet,
ultramarine green, French blue, new blue, permanent blue, oriental blue,
Gmelin's blue, Guimet's blue.
IR ANALYSIS LAB
Getty Conservation Institute
IR ANALYSIS CONDITIONS
Spectra-Tech IRIlS
= 4 cm-'
= 200
Range = 4000-800 cm-'
Microscope
Bulk sample on BaF,
Resolution
Scans
40 3600 320 2800 240 20 180 160 140
Ultramarine
600 40
B l ue
1 99
Infrared Reference Spectra
Malachite :
basic copper carbonate, CuC03 ·Cu(OH) 2
Basic Copper Carbonate
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Forbes Collection
Basic copper carbonate naturally occurs in two mineral forms, azurite (blue:
2CuCO,·Cu(OH),) and malachite (green: CuCO,·Cu(OH),). The two minerals
usually occur together. Pigments are prepared by careful selection, grinding,
washing, and levigation. Both are sensitive to acids. The synthetic pigment is
called green verditer and is a pale greenish blue.
Unknown
Green, opaque, powder
1530-1350 cm·'
900--650 cm·'
3700-3100 cm·'
1100-1000 cm·'
CO,'·
o-co
SYNONYMS: Basic copper carbonate, azurite, mountain blue, malachite,
mountain green, blue verditer, blue bice, green verditer, green bice, mineral
green.
stretching bands
bending bands
O-H
stretching bands
O-H
bending bands
IR ANALYSIS LAB
Analytical Answers, Inc., 1 2/96
IR ANALYSIS CONDITIONS
Bio- Rad FTS
40
= 4 cm-'
= 50
= 4000-750 cm-'
Microscope
Bulk sample on BaF,
Resolution
Scans
Range
40 360 320 280 240 20 1800 1600
60 40
Basic Copper Carbonate
G reen
Copper Acetate
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
Kremer-Pigmente
Germany
Green
1660-1550,1450-1400,-1050,-1020,-925 cm·' acetate ion
stretching and bending bands
3550-3200 cm·' antisymmetric and symmetric O-H
Basic copper acetate i s a greenish blue crystalline powder that i s called
verdigris. Its preparation, known since ancient times, involves exposing copper
to vapors of fermenting solutions. The crystals are soluble in water and acids
and are toxic. The pigment is unstable and can leave a black residue upon
decomposition. When combined with terpenoid resins, such as Venice
turpentine, verdigris forms copper resinate. Verdigris is used as a pigment and
a textile dye.
SYNONYMS: Copper acetate, verdigris, copper resinate, crystals of Venus,
cupric acetate.
stretching bands
IR ANALYSIS LAB
Getty Conservation Institute, 1 0/14/92
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
=4
= 200
Range = 4000-800 cm-'
Microscope
Bulk sample on BaF,
Resolution
cm-'
Scans
400 3600 320 280 240 20 180
Copper Acetate
60 40
G reen
200
Appendix I I
Madder
(CI Natu ral Red
PROVENANCE
SOURCE
APPEARANCE
8)
H. Schweppe
Madder
Madder is a natural red dye obtained from the root of the Rubia /inc/orium
plant, which is cultivated in Europe and Asia Minor. The dye contains three
principal colorants: alizarin (red), purpurin (red), and xanthine (yellow). The
dye is extracted from the dried, powdered root as a precipitate when it is boiled
in water. Alum lakes of madder, madder lake, and rose madder were used as
artists' pigments. Madder was commonly used to dye textiles until synthetic
alizarin was developed in 1 868.
Germany
Red, powder
SYNONYMS: Madder lake, alizarin (natural), CI Pigment Red 83.
CHARACTERISTIC IR
ABSORPTION BANDS
3600-3200 cm"'
O-H
stretching band
31 00-2800 cm"'
C-H
stretching bands
1 740-1 640 cm"'
C=O
1 620-1420 cm"'
1 480-1300 cm"'
aromatic bands
1 300-900 cm"'
CoO stretching bands
C-H
stretching bands
bending bands
IR ANALYSIS LAB
Getty Conservation Institute, 2/24/92
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
= 4 cm-'
Microscope
Bulk sample on BaF,
=
Resolution
Scans = 200
Range 4000-800 cm-'
Comment: baseline corrected
40 360 320
60 40
Madder
Red
Dragon's Blood
Dragon's Blood
PROVENANCE
SOURCE
APPEARANCE
CHARACTERISTIC IR
ABSORPTION BANDS
A. F. Suter
&
Co.
Unknown
Dragon's blood is a transparent, red, resinous exudation from the rattan cane
palm, Calamus draco, that grows in eastern Asia. It is soluble in alcohol but
insoluble in water. The color is fugitive when exposed to air but remains when
protected by a resin film. It is used in stain varnishes, marble coloring, paints,
and lithography.
Red, resinous, powder
SYNONYMS: Called
3600-3200 cm"'
O-H
stretching band
31 00-2800 cm"'
C- H
stretching bands
1 740-1 640 cm"'
1 650-1600 cm"'
C=O stretching band
C=C stretching band
1 620-1420 cm"'
aromatic bands
1 480-1300 cm"'
C-H
bending bands
1 300-900 cm"'
CoO
stretching bands
cinnabaris by the ancients and by Pliny.
IR ANALYSIS LAB
Getty Conservation Institute
IR ANALYSIS CONDITIONS
Spectra-Tech IR�S
= 4 cm-'
= 200
Range = 4000-800 cm-'
Microscope
Bulk sample on BaF,
Resolution
Scans
40 360 320 280 240 20 180 160 140 120 10 80 60 40
Dragon's Blood
Red
G l ossary
absorbance
The amount of light absorbed by the sample at any specific wavelength. The intensity of a
'
band in absorbance u n its is d i rectly proportional to the concentration of sample responsible
for the absorption band at that wave length. I t is useful to plot the y-axis of I R spectra in
absorbance u n its (absorption bands ascending, or peaks) for q u antitative analysis meth
ods, spectral searching, and su btraction routines.
absorption
The absorption of specific wavelengths of energy by an atom or molecu le that results in
an el ectron ic, vibrational, translational, or rotational motion.
absorption bands (or peaks)
A spectral absorption recorded as a band (transmittance u n its) or as a peak
(absorbance u n its) .
ampl itude
attenuated total reflection (ATR)
The i ntensity, vol u m e , o r magnitude o f a wave.
An older, although sti l l - used , name for i nternal reflection spectroscopy. See i nternal
reflecti o n .
baseline
The position of a spectral c u rve when the sam ple is n o t absorbing a n y radiatio n . U nder
optimized conditions, the baseline occurs at 1 00 % transmittance, or 0 . 0 absorbance.
blackbody radiation
A radiator that e m its a conti nuous spectrum of wavelengths with no missing freq uencies.
The term is based on the thermodynamic principle that any material that emits all wave
lengths when it is hot m ust absorb all wavelengths when it is cold. The color of a totally
absorbing material is black, and thus the perfect emitter was given the name blackbody
(Crooks 1 978) .
combi nation band
A weak absorption band that is the product of the com b i n.ation of two, or even three,
strong vibrational q uanta. The frequency of the band is equal to the sum of the freq u e n
c i e s of the originating b a n d s . A combi nation b a n d f o r a strong absorption b a n d at
1 600 c m - 1 and one at 1 2 50 c m - 1 would occ u r at 2 850 c m - 1 .
computer search routine
A comp uterized li brary search program typically based on the comparison of peak position
and intensity of an u n known spectrum versus those i n thousands of reference spectra.
Conne's advantage
An advantage of FT- I R spectroscopy over dispersive I R , due to FT- I R ' s wavelength
accu racy. Because in FT- I R a laser is used to cal ibrate the wavelengths in the spectru m ,
accu racy is ensured without a n y external calibrati o n . T h i s accu racy is i m portant f o r the
comparison of spectra to one another, as is done in l i b rary searc h i n g and spectral sub
traction routines.
correlation chart
A chart showing most common IR group freq ue ncies and their positions, ranges, and rela
tive intensities.
202
Glossary
deconvol ution
A mathematical routine that operates on two or more overlapping bands, reducing the
l i n e width of i ndivid ual components, thereby i m p roving the spectral resolutio n .
degrees of freedom
Allowed molecular motions-translational, rotati onal, a n d vibrational-with i n a molecule.
The degrees of freedom depend on the n u m ber of atoms i n a molecule and its symm etry.
detector
diffraction
An instrument or cell capable of converting rad iant energy i nto an electrical signal.
A physical phenomenon i n w h ich radiation is dispersed or scattered when it passes by a
sharp edge. I n IR m icrospectroscopy, diffraction may occ u r when the beam passes through
the apertures.
diffuse reflection (DRIFTS)
A n IR analysis tec h n i q u e i n which the IR beam is diffusely reflected from the su rface of a
sam ple. It may be used with rough or porous samples, such as samples collected on silicon
carbide paper.
d ispersion
electromagnetic spectrum
Separation of rad iant ene rgy into d iscrete wavelengths.
The total range of electromagnetic radiatio n . The IR region is one small part of the elec
tromagnetic spectru m .
electronic transition
A change i n the energy levels o r spin d i rections of electrons with the absorption o r emis
sion of energy.
far infrared (far- I R or F I R)
The region of the electromagnetic spectrum (500-20 cm- 1 ; 20-500 I-l-m) that falls
between the m i d - I R and the m icrowave region . The far- I R region is well suited to the
study of organometal lic or i norganic compounds and is useful in the identification and dif
ferentiation of many m i nerals and colorants.
Fourier transform
frequency
(v)
A complex mathematical function that converts an i nterferogram into a spectru m .
The n u m be r o f oscillations, or waves, p e r u n i t time-i . e . , cycles p e r seco n d . T h e term i s
also used t o deSignate t h e specific wave n u mber o f an absorption band.
functional group
A group of two or more atoms with i n a molecule that i m part a given characteristic to that
molecule ( e . g . , hydroxyl, carbonyl). Most functional groups absorb I R radiation at repro
ducible freq ue ncies, known as group freq uencies.
fundamental
The frequency correspon d i n g to a first-order vibration of the molecule. The fundamental
vibration will produce the strongest absorption band for a given transition of a functional
gro u p .
group freq uency
A freq uency that is associated w i t h a particular functional group ( i . e . , carbo nyl,
C=O)
and
is c o m m o n t o all molecules contained i n that gro u p . G r o u p freq uencies are used t o deter
m i n e the chemical class of a material.
i nterferogram
A plot of intensity versus d isplacement of an optical light path . This plot is the measured
result of radiation that has passed through an interferometer; it may be converted to a
spectrum using a Fourier transform mathematical process.
interferometer
An apparatus with a moving m i rror and a fixed m i rror that can modulate a spectrum into
an interferogram, thus allow i n g all freq ue ncies to be measured at one time.
internal reflection spectroscopy (I RS)
An IR analysis tec h n i q u e i n which the sam ple is placed i n optical contact with a high
refractive - i ndex element. When an IR beam is passed through the eleme nt, a slight pene
tration of the beam i nto the sam ple occurs. This tech n i q u e is usefu l for su rface analysis.
G lossary
microspectrophotometer
2 03
An I R m icroscope coupled to an I R spectrometer, to compose a system capable of acq u i r
i n g IR spectra of m icroscopic size samples.
m i d-infrared ( m i d - I R or M I R)
The region in which most fundame ntal vi brations for organic molecules occu r
(4000-500 cm- 1 ; 2 . 5-20 f.Lm ) . T h i s region can b e subd ivided i nto t h e group frequency
region (4000-1 300 c m -1 ; 2 . 5-8.0 f.Lm) and the fingerprint region ( 1 300-500 c m - 1 ;
8 . 0-20 f.Lm).
modulate
To change a wave fo rm . An i nterferometer modulates, or changes, the wave form of light
from a s i n e pattern to an interferogram pattern .
monochromator
A device that separates light i nto its spectrum of freq uencies. I n dispersive I R spectrom
eters, a monochromator i s used to disperse the rad iation prior to passi n g each wavelength
through the sam ple.
m u ltiplex advantage (Fel lgett's advantage)
The major advantage of FT- I R spectrometers over d ispersive spectrometers. FT- I Rs mea
sure all wavelengths of IR rad iation s i m u ltaneously, w h i l e dispersive spectrophotometers
measure one resolution element at a time. Thus, an FT- I R can acq u i re a whole spectrum i n
t h e time i t takes a d i spersive spectrometer t o collect o n e resolution element.
near i nfrared (near- I R or N I R )
The IR region from 1 4,000 to 4000 c m - 1 (0.7-2 . 5 f.L m ) . Spectra gene rated i n the near- I R
region consist entirely o f overto nes, combi nations, and combi nations o f overtones of
fundamental vi bration modes from the m i d - I R region.
n o i se
Small, rapid fluctuations usually observed i n the baseline of the spectru m . Noise is associ
ated with i nstrument conditions rather than being specific to a sample.
overtone
A weak vi brational transition occurri n g at approximately twice the freq uency of a strong
fundamental absorption frequency. A n overtone band for a strong absorption band at
1 700 c m - 1 would occur at 3400 c m - 1 .
path length
The thickness of a measured medi u m . The absorption i ntensity is proportional to the
path length of measurement. This relationship is often observed when a sam ple i s too
thick and thus absorbs too strongly, p roducing satu rated absorption bands.
qual itative
quantitative
reflectance
Analysis used to determine what kind of material i s present.
Analysis used to determine how m uch of a material is present.
The amount of rad iation reflected from a sam ple. A n IR spectrum plotted in reflectance
u n its can usually be converted to appear as a transmittance spectrum with the Kubelka
M u n k or Kramers - K ro n i g transformations for diffuse reflection and specular reflection,
respectively.
reflection
Radiation that bounces off the su rface of a material after contact.
refraction
The change in angle of a light path as it passes from one medium i nto another with a dif
ferent refractive i n dex.
resolution
The abil ity of an i n strument to separate two closely occurring absorpti ons. T h i s abil ity i s a
function of i nstrumental and spectral parameters such as detector sensitivity, absorption
intensity, absorption freq uency, interferometer scan distance, and signal-to-noise ratio .
rotational transition
T h e rotation o f a molecule around its center o f mass with t h e absorption or emission
of en ergy.
204
Glossary
selection rule
A rule that determ ines whether a given vibration w i l l be seen in the spectru m , based on
the symmetry of the molecule. The primary selection rule, or req u i rement, for active IR
absorptions is that the vibration m u st result i n a change i n the dipole moment of
the molecule.
signal-to-noise ratio
source
spectral l i n e
The i n tensity of the recorded absorption band versus the inten sity of noise.
A high-temperature body used to gene rate rad iant energy.
Absorption related specifically to a q u antu m energy change. This absorption is never actu
ally seen as a l i n e but rather as a band or peak .
spectrophotometer
An i nstrument for record i n g the i n tensity and frequency of spectral absorptions. Also
sometimes referred to as a spectrometer.
spectroscopy
The study of the interaction of l i ght and matter. The term is also used to specify the tech
n i q u e of record i n g and studying spectra.
spectrum ( p I . , spectra)
A recorded tracing of the amount of radiation absorbed at each frequency over a given
spectral range of i n terest.
specular reflection (external reflection)
A type of reflection in which the reflection angle of a beam is eq ual to the i ncident angle,
as i n a m i rror.
s u btraction
A mathematical routine for compari ng two spectra by su btracti n g the absorption bands of
one from the other. It is useful for e l ucidating small changes between two similar spectra
that may otherwise be overlooked.
throughput advantage
(Jacq u i not's advantage)
An advantage of FT- I R over dispersive instru ments. A greater amount of rad iation
reaches an FT- I R detector than reaches a detector for a dispersive i nstru ment, because of
the lim itations of the monochromator slit. This greater energy throughput gives FT- I R
more sen sitivity, which is often needed for reflection tech niques.
translational tran sition
The movement of an entire molecule to a new position i n space d u e to the absorption or
em ission of energy.
transmission
transm ittance
The passage of radiation through a material without its being absorbed or reflected.
The amount of radiation transm itted through a sam ple. Transm ittance is equ ivalent to the
logarithmic reCiprocal of absorbance. IR spectra are often pl otted with the y-axis givi n g
percent transm ittance (absorption bands desce ndi ng) t o i nc rease the size of smaller
absorption bands i n relation to more i n tense absorption band s .
vibrational tran sitions
The change i n b o n d angles or bond lengths w i t h i n a molecule d u e t o t h e absorption or
em ission of energy. Molecular vibrations account for the strongest absorption bands i n an
IR spectru m .
wavelength
wave n u mber
(( 11A.))
The distance between two successive maxima or m i n i m a of a wave-i . e . , the length of
one wave.
The n u m ber of waves per u n i t length . Wave n u m ber u n its are commonly used in IR spec
troscopy and are ex pressed i n cm -' .
Suppliers
Becton Dickinson, Acute Care, 1 Becton Dr., Franklin Lakes, NJ 074 1 7; ( 20 1 ) 8476 8 00. Sells Beaver blades and other microsurgical tools.
Bio-Rad, Digilab Div., 237 Putnam Ave., Cambridge, MA 02 1 39; ( 6 1 7) 8 6 8 -4330.
Sells FT-IR spectrophotometers, microscopes and other accessories, thermal and chro
matographic IR attachments.
Bomem International, 7800 Quincy St., Willowbrook, IL 6052 1 ; ( 7 0 8 ) 9 8 6 - 1 090.
Sells dispersive and FT-IR spectrophotometers along with many accessories, including
microscopes.
Bruker Instruments, Inc., 19 Fortune Dr., Billerica, MA 0 1 82 1 ; ( 5 0 8 ) 6 6 7-9580. Sells
dispersive and FT-IR spectrophotometers along with many accessories, including
microscopes.
Buck Scientific, Inc., 58 Fort Point St., East Norwalk, CT 06855-1 097; (203) 8 5 39444. Sells dispersive and FT-IR spectrophotometers along with many accessories.
Carolina Biological Supply Co., 2700 York Road, Burlington, NC 2 72 1 5; ( 8 00) 334555 1 . Sells Caroplastic polyester for embedding.
Castolite Co., P. O. Box 39 1 , Woodstock, IL 60098; ( 8 1 5 ) 338-4670. Sells Castolite
polyester for embedding.
Conservation Materials, 1 2 75 Kleppe Lane, Suite 10, Sparks, NV 89431 ; ( 702) 331 0582. Sells conservation products, including Rhoplex AC-33.
Digilab-see Bio-Rad.
Ernest E. Fullam, Inc., 900 Albany Shaker Road, Dept. AL, Latham, NY 1 2 1 1 0- 1 4 9 1 ;
( 5 1 8 ) 78 5-5533. Sells microanalysis tools and containers, silicone molds for preparing
cross sections.
Galactic Industries Corp., 395 Main St., Salem, NH 03079; ( 603) 8 9 8 -7600. Sells
spectral conversion and search software, data processing routines, including three
dimensional spectral processing routines.
Graseby Specac, 301 Commerce Dr. , Fairfield, CT 06430; ( 8 00) 447-2558. Sells acces
sories for IR spectrometers, gas cells, optical crystals, sample preparation equipment.
Harrick Scientific, 8 8 Broadway, P. O. Box 1 2 8 8 , Ossining, NY 1 0562; ( 9 1 4 ) 7620020. Sells accessories for IR spectrometers, optical crystals, sample preparation
equipment, custom accessories (such as ATR and DRIFTS units).
High Pressure Diamond Optics, 231 Gianconda Way, Suite 1 03, Tucson, AZ; ( 520)
544-9338. Sells high- and low-pressure diamond anvil cells; diamond microtoming
knives.
International Crystal Laboratories, 1 1 Erie St., Garfield, NJ 07026; ( 20 1 ) 478-8944.
Sells accessories for IR spectrometers, optical crystals, sample preparation equipment.
lASCO, 8 649 Commerce Dr., Easton, MD 2 1 60 1 ; ( 8 00) 333-5272. Sells dispersive
and FT-IR spectrophotometers, accessories including microscopes.
206
Suppliers
KVBIAnalect, 1 7 8 1 9 Gillette Ave., Irvine, CA 92 714; ( 7 1 4 ) 660-8 8 0 1 . Sells dispersive
and FT-IR spectrophotometers, accessories including microscopes.
Ladd Research Industries, Inc., 1 3 Dorset Lane, Williston, VT 05495; ( 802) 658496 1 . Sells general microscope supplies a n d acrylic, epoxy, a n d wax materials for
embedding.
Mattson Instruments, 1 00 1 Fourier Dr., Madison, WI 5 3 7 1 7; ( 6 0 8 ) 8 3 1 -5 5 1 5 . Sells
dispersive and FT-IR spectrophotometers, accessories including microscopes.
McCarthy Scientific Co., P. O. Box 5332, Fullerton, CA 92635; ( 7 1 4 ) 526-2742. Sells
optical crystals, sample preparation equipment.
Midac Corp., 1 79 1 1 Fitch Ave. , Irvine, CA 92714; ( 7 1 4 ) 660-855 8 . Sells FT-IR sys
tems, portable IR air-monitoring systems.
Minitools, 634 University Ave., Los Gatos, CA 95030; (408) 3 9 5 - 1 5 8 5 . Sells micro
tools, micromanipulation devices, microdrills.
Nicolet Instrument Corp., 5225-5 Verona Road, Madison, WI 5 3 7 1 1 ; ( 6 0 8 ) 276-
6 1 00 . Sells FT-IR spectrophotometers, accessories including microscopes.
Perkin-Elmer Corp., 7 6 1 Main Ave., Norwalk, CT 06859; ( 8 00) 762-4000. Sells dis
persive and FT-IR spectrophotometers, accessories including microscopes, other types
of analytical instrumentation.
Photometrics, Inc., 1 5 8 0 1 Graham St., Huntington Beach, CA 92649; ( 7 1 4 ) 8 95-
4465. Provides searches of numerous commercial IR libraries.
Pike Technologies, 29 1 9 Commerce Park Dr., Madison, WI 5 3 7 1 9; ( 6 0 8 ) 274-272 1 .
Sells IR accessories, microscope computer-controlled mapping stages.
Shimadzu Scientific Instruments, Inc., 7 1 02 Riverwood Dr. , Columbia, MD 2 1 046;
( 8 00) 477-1 227. Sells dispersive and FT-IR spectrophotometers, accessories including
microscopes, other types of analytical instrumentation.
Spectra-Tech ( Spectra Technology), Inc., 2 Research Dr., Shelton, CT 06484-0849;
(203 ) 926-8998. Develops and sells innovative IR accessories, including microscopes,
IRj.LS microspectrophotometers, compression cells that use salt plates or diamond win
dows, roller knives. Also sells 3M disposable IR cards containing thin polymer films for
sample preparation.
Structure Probe, Inc., P. O. Box 656, West Chester, PA 1 93 8 1 ; ( 2 1 5 ) 43 6-5400. Sells
microanalysis tools and containers, silicone molds for preparing cross sections.
Ted Pella, Inc., P. O. Box 23 1 8, Redding, CA 96099; ( 9 1 6 ) 243-2200. Sells acrylic,
epoxy, and wax materials for embedding, along with several types of Peko silicone
embedding molds.
Union Carbide, 39 Old Ridgebury Rd., Danbury, CT 068 1 7; (203 ) 794-5300.
Manufactures and sells Parylene.
Ward's Natural Science, P. O. Box 92912, Rochester, NY; ( 800) 962-2660. Sells Bio
Plastic polyester for embedding.
Whatman, Balston Div., 1 00 Ames Pond Dr., Tewksbury, MA 0 1 8 76; ( 800) 343-4048 .
Sells Balston dry air systems to purge I R spectrometers.
Wig-L-Bug, Crescent Dental Manufacturing Co., 7750 47th St., Lyons, IL 60534;
(708) 447-8050.
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Index
Amides, absorption band frequencies of,
Note: Italicized letters ( and t following
page numbers indicate figures and tables,
respectively,
46-47, 48t, 49(
Amplitude, of radiation waves, 5 , 6(
Anhydrides, absorption band frequencies of,
A
96-97, 98(
Anhydrite, absorption bands for, 1 1 7
Animal glue, reference spectrum for, 1 8 1 (
Anionic groups, absorption bands for, 1 1 6t,
Absorbance mode, for spectral display,
84(, 85
Absorbance ratio method, 1 2 3-124
Absorption
in IR experiments, 1 3
theory of, 6-1 2
Absorption bands
for anionic groups, 1 1 6t, 1 1 6-1 1 8
correlation charts for, 99, 99(
frequency of, 82-83
for selected functional groups, 95t,
1 1 6-1 1 8
Aperture(s), i n I R microspectroscopy,
95-98
96-97, 98(
34t,
36, 36(
for infiltration prevention, 37
IR transmittance spectrum of, 1 1 0(, 1 9 1 (
Acryloid B-72
IR spectra for, 43, 44(, 1 1 0(
with expanded carbonyl region, 6 1 (
reference spectrum for, 1 9 1(
Adhesive tape, for fiber collection, 32
Adhesives, chemical analysis methods
for, 1 8t
Adoration o( the Magi (Mantegna), infrared
analysis of, 1 52-154, 1 5 3(
Air pollutants, chemical analysis methods
for, 1 8 t
Alcohols, absorption band frequencies of,
96, 97(
Aldehydes, absorption band frequencies of,
96-97, 98(
Alkali halide pellets, in IR microspec
troscopy, 71(
Aluminum foil, for sample storage, 22,
Aluminum mirrors, in reflection
absorption, 63
Amber, spectral identification of, 1 04
26
71,
72, 76
in infrared spectrum, 1 1
attributes of, 82-83
intensity of, 83
and concentration of absorbing mole
cules, 85, 122-123
and dipole moment, 122
in quantitative analysis, 1 2 1
for polyester, 37
shapes of, 8 3
for water vapor, 9(
Accelerated aging studies, 1 3 3
Acetone, a s solvent, 3 0
Acids, absorption band frequencies of,
Acrylic, 1 9 1
for embedding of paint cross sections,
infrared transmission characteristics of,
95t,
97-98, 98(
and cross section analysis, 76-77, 77(
and diffraction effects, 73-74, 75(
effects of varying area of, 72-73, 74(
selection of, 72(
Arabic gum, reference spectrum for, 1 79(
Archaeological objects, infrared analysis
of, 1 3 1
Chumash Indian paints, 1 4 1 - 1 44, 143(,
1 44(, 145(
Dead Sea Scrolls, 1 66-170, 1 69(, 1 70(
Area mapping microspectroscopy, '77, 78(
Art objects
infrared analysis of, 1 3 0- 1 3 1
cellulose nitrate sculptures, 1 63-165,
1 66(, 1 67(
paintings of Italian masters
cross sections in, 1 52-1 5 5
ultramarine pigments in, 1 34-1 3 8,
1 3 5(, 1 3 6(
inorganic substances in, 1 7
organic substances in, 1 7- 1 8
Artist's brush, 2 0 , 2 1 (
for cross section sampling, 3 3
in microtoming, 4 1
Artists' Pigments handbook series, 1 1 3
ATR objective, 79, 80(
Attenuated total reflection (ATR), 60, 65,
See also Internal reflection
spectroscopy
case studies using, 1 60-163, 1 6 8
IR spectra of Acryloid B-72 collected by,
Barium sulfate
mid-IR absorption band regions for, 1 1 9t
reference spectrum for, 1 96(
Baseline, spectrum
as quality check, 8 8 , 8 8 t
sloping, 8 8 , 8 9 (
Basic copper carbonate, reference spectrum
for, 1 99(
Beam condensers, 52, 54(
in internal reflection spectroscopy, 67
Beer's law, 85, 122-123
Beeswax, IR transmittance spectrum for,
1 0 1 (, 1 84(
Bending vibration, 1 1
Benzene, a s solvent, 29(
BEVA 3 7 1 , reference spectrum for, 1 92(
Binders
in California rock paintings, 142-144
chemical analysis methods for, 1 8 t, 34
IR analysis of paints and, 120
Black pigments
mid-IR absorption band regions for, 1 1 9t
Blood
as binder in Chumash Indian paints,
142-143
dried, IR transmittance spectrum for, 143(
Blue pigments
mid-IR absorption band regions for, 1 1 9t
reference spectra for, 1 97(-1 98(
ultramarine pigments, infrared analysis of,
1 34-1 3 8, 1 3 5(, 1 3 6(
Bohr, Niels, atomic model of, 7, 7(
Brown, mid-IR absorption band regions
for, 1 1 9 t
C
B
Calcite (calcium carbonate)
absorption bands for, 1 1 6, 1 1 6t
and rabbit-skin glue, IR transmittance
spectra for mixture of, 1 2 1 (
infrared transmittance spectrum of, 1 1 5(
reference spectrum for, 194(
Calcium fluoride, infrared transmission char
acteristics of, 4 8t
Calcium oxalate, as weathering product,
studies of, 1 3 3-1 3 4
Calcium sulfate, reference spectra for,
Badakhshan mines, Afghanistan, lapis lazuli
from, 1 3 7(, 1 37-138
Balsam, reference spectra for, 1 8 6(-1 8 7(
Barite
absorption bands for, 1 1 7
I R transmittance spectrum for, 1 1 5(
Barium fluoride
for elimination of interference fringes, 76
Calibration curve, 1 2 3
Capillary tubes
for liquid sampling, 2 6
in solvent extraction, 3 1
Carbon dioxide, extraneous bands produced
by, 8 8t, 90-91
Carbon disulfide, as diluent, 5 1
44(, 6 1 (
microspectroscopy, 7 9
Autoscale subtraction computer
routine, 124
Azurite, absorption bands for, 1 1 6,
1 1 6t, 1 1 7
1 94(, 1 95(
231
Index
Carbon double bond region
in polymer identification, 1 1 2
in spectral interpretation, 94
Carbon tetrachloride, as diluent, 5 1
Carbonates, absorption bands for, 1 1 6t,
1 1 6-1 1 7
Carbonyls, absorption band frequencies of,
95t, 96-98, 98f
Carnauba wax, reference spectrum for, 1 84f
Case studies
cellulose nitrate sculptures, 1 6 3-165,
1 66f, 1 67f
Chumash Indian paints, 141-144, 143f,
144f, 145f
creosote lac resin, 1 38-1 4 1 , 140f
Dead Sea Scrolls, 1 66-170, 1 69f, 1 70f
furniture surface treatments,
144-148, 147f
mapping microspectroscopy, 152-155
Parylene oxidation, 1 5 9-163, 1 6 1f, 1 62t
reflection versus transmission analysis,
148-152
ultramarine pigments, 1 34-1 38,
1 35f, 1 3 6f
Vikane interaction with solid materials,
1 55-159, 158f, 1 5 9f
Casein, reference spectrum for, 1 82f
Cassegrain reflective optics objective, 80f
Cat-hair brush, 20, 21f
in microtoming, 41
Cellulose nitrate, 163, 190
reference spectrum for, 1 90f
sculptures, infrared analysis of, 1 63-165,
1 66f, 1 67f
Cellulosic
IR transmittance spectrum for, 11 Of
spectral identification of, 109
Cennini, Cennino, 1 3 4
Ceramics
chemical analysis methods for, 1 8t
Native American, infrared analysis of,
1 38-14 1 , 1 40f
Cerussite, absorption bands for, 1 1 6, 1 1 6t
Cesium bromide, infrared transmission char
acteristics of, 48t
Cesium iodide, infrared transmission charac
teristics of, 48t
C-H stretching region
in polymer identification, 1 1 1
in spectral interpretation, 94
Chalk
IR transmittance spectrum for, 1 1 5f, 1 94f
mid-IR absorption band regions for, 1 1 9t
Chemical analysis techniques
combining, 1 8-1 9
comparison of, 1 7t
order of application, 1 8 t
Chloroform, a s solvent, 29f, 3 0
Chromatography, 1 7t, 1 2 1
Chumash Indian paints, infrared analysis of,
141-144, 1 43f, 144f, 145f
Clay, 195
IR transmittance spectrum of, 1 15f, 1 95f
mid-IR absorption band regions for, 1 1 9t
thermal transformations in lattice structure of, 1 1 8
Cloth-lap procedure, 48
Coatings
chemical analysis methods for, 1 8t
IR analysis methods for, 45t
Coblentz, William W., 1
Collagen, in parchment, 1 6 7
Colorants. See also Pigments
chemical analysis methods for, 1 8t
infrared analysis of, 132
spectral identification of, 1 1 3-120
Combination bands, 1 1
Commercial liquid cells, 5 1
Compression cells, 71f, 75-76
interference fringes produced by, 76
Computer libraries search programs, for spec
tral interpretation, 92-93
Computer spectral subtraction methods,
124-125
Concentration, sample, determination
of, 123
Consolidants, chemical analysis methods
for, 1 8t
Container storage, of samples, 22
Contamination of sample, avoidance of, 23
Contour mapping microspectroscopy,
78, 79f
Convolution, 125-126
Cooley, James, 2
Copal, IR transmittance spectrum for,
1 06f, 1 8 7f
Copper acetate, reference spectrum for, 1 9 9f
Copper carbonate, basic, reference spectrum
for, 1 99f
Corrosion products
chemical analysis methods for, 1 8t
infrared analysis of, 132
Creosote lac resin, infrared analysis of,
1 38-14 1 , 140f
Cross section samples
collection and preparation procedures,
25t, 33-41
embedded, reflection versus transmission
analysis of, 148-152
embedding of, 34-37
microspectropic analysis of, 72f,
76-77, 77f
microtoming of, 37-41
o
Dammar, reference spectrum for, 188f
Dead Sea Scrolls, infrared analysis of,
1 66-170, 1 69f, 1 70f
Deconvolution, 125-127, 1 28f
Degrees of freedom, 8-10
for triatomic molecule, 1 0f
Depletion measurements, vapor-phase,
1 55-1 5 9
Derivative spectroscopy, 1 2 5 , 127f
Detector response, 12f, 12-13
Deterioration studies, infrared spectroscopy
in, 1 3 3-134
cellulose nitrate sculptures, 1 63-165
Dead Sea Scrolls, 166- 1 70
Diamond cells, 58-59, 59f
interference fringes produced by, 76
Diamond, IR transmission characteristics of,
48t, 59
Diamond knives, for rotary microtomes,
37-38, 38f
Die, pellet, 53f, 54-55
Difference spectra, 125
Diffraction, apertures and, 73-74, 75f
Diffuse reflection, 60f
Diffuse reflection spectroscopy (DRIFTS), 60,
63-65
accessory for, 64f
introduction of, 60
IR spectra of Acryloid B-72 collected by,
44f, 61f
for liquid analysis, 51
spectral alterations due to, 6 1 t
Digilab, 2
Dipole moment
change in, as selection rule, 1 1
intensity of absorption bands and, 122
Direct measurement method, 123
Dispersive spectrophotometer, grating-type,
85-86
Disposable infrared cards, 56
Documentation, sample, 2 1 -22, 24, 7 1
Dragon's blood, reference spectrum for, 200f
DRIFTS. See Diffuse reflection spectroscopy
Dyes. See Colorants
E
EDS. See Energy dispersive spectroscopy
Egg yolk, reference spectrum for, 1 83f
Electromagnetic radiation
absorption theory of, 6-12
spectral regions of, 4, 5f
types of, 4
wave theory of, 4-6, 6f
Electronic transition, 8
Electrons, in Bohr's atomic model, 7
Elemi, reference spectrum for, 188f
Embedding, of cross section samples, 34t,
34-37, 3 6f, 37f
infiltration during, 35-37
and microspectroscopic analysis, 76
molds and embedding media blocks used
for, 35f
optimal for microtoming, 35, 39, 39f
with polyester resin, 34-35
trimming to produce trapezoid tip, 39, 40f
Energy dispersive spectroscopy (EDS), 1 7t
Epoxy, for embedding and microtoming of
paint cross sections, 34t
Eppendorf GELoader, polypropylene tips
for, 3 1
Esters, absorption band frequencies of,
96-97, 98f
Ethanol, as solvent, 30
Ethnographic materials, infrared analysis
of, 1 3 1
case study, 1 38-141
Ethyl acetate
IR transmittance spectra for, 140f
as solvent, 29f, 30
External reflection, 60, 60f
reflection-absorption, 63
specular, 62-63
External reflection accessory, variable
angle, 62f
Eye blades, 2 1
Eyelash brush, 2 0 , 21f
in microtoming, 4 1
F
Far-infrared (FIR) region, 14
Fast Fourier transform (FFT) algorithm,
discovery of, 2
Fellgett, Peter, 1-2
Fibers
chemical analysis methods for, 1 8 t
contaminants, 23
flattening of, 32-33, 58, 75-76
advantages to, 60
infrared analysis methods for, 45t
microspectroscopic analysis of, 72f, 72-74
reflection analysis of, 67
sample collection and preparation proce
dures, 25t, 32-33
scattering caused by, 56
transmission analysis of, 59-60
Fillers (inorganic), chemical analysis methods
for, 1 8 t
Films
on diamond cells, 58-59, 59f
infrared analysis methods for, 45t
preparation of, 56-57
reflection analysis of, 67
thickness of, calculating, 56, 57
232
transmission analysis of, 56-59
on transparent supports, 56-58
unsupported, 56
and interference fringes, 56, 57{
Fingerprint region, 14
and identification of material, 83
in polymer identification, 1 1 2-1 1 3
i n spectral interpretation, 94
Finishes, chemical analysis methods for, 1 8t
FIR region. See Far-infrared region
First-order vibration. See Fundamental
vibration
Fish glue, reference spectrum for, 1 8 1{
Flattening of sample, 32-33, 58
advantages to, 60
methods for, 75-76
Flourinated oil (Fluorolube), mixture of
particles with, 57
Forceps, in IR microspectroscopy, 71
Fourier self-deconvolution,
125-127, 1 28{
Fourier transform infrared (FT-IR) spectrometers, 1-2
attachment of microscopes to, 68
and plotting formats, 85
resolution on, 86
Frequency
of absorption bands, 82-83
of radiation waves, S
ad vantages of using, 6
FT-IR spectrometers. See Fourier transform
infrared spectrometers
Functional group(s), 1 1-12
absorption band qualities and information
about, 82, 83
correlation charts for, 99, 99{
selected, absorption band frequencies of,
95t, 95-98
in spectral interpretation, 93-95
Functional group imaging. See Molecular
mapping
Fundamental transition, 9
Fundamental vibration, 1 1
Furniture surface treatments, infrared analysis
of, 144-152
G
Gamma radiation, 4, 5{
Gas(es)
interaction of solid material with, vapor
phase depletion measurements
for, 1 54-158
IR analysis methods for, 45t
rotational absorption bands of, 9{, 50
sample collection and preparation procedures, 24-25, 25t
transmission analysis of, 50
Gas cell, 50, 50{
for depletion studies, 1 57{
Gas chromatography (GC), 1 7t
application of, 142
GC-IR interface, 50
Gelatin
collagen denaturation to, 1 6 7
I R transmittance spectrum for, 98{, 1 82{
Gems, chemical analysis methods for, 1 8 t
Germanium, a s IRS element, 66
Gettens Collection, 92, 1 09
Glass
absorption bands for, 1 17
chemical analysis methods for, 1 8t
infrared transmission characteristics of,
46, 48t, 49{
Glass containers, for sample storage, 22
Glass depression slide, 22{, 22-23
Index
Glass knives, for rotary microtomes, 38,
38{, 39{
Gold mirrored surface
in reflection-absorption, 63
in solvent extraction, 30
Grazing-angle spectroscopy, 63, 79
Green pigments
mid-IR absorption band regions for, 1 1 9t
reference spectra for, 1 99{
Grinding of sample, 54
anomalies produced by, 55
Group frequencies, 12
Gum(s)
IR transmittance spectra for, 1 0 1{,
1 79{-1 80{
spectral identification of, 108
Gypsum
absorption bands for, 1 1 7
mid-IR absorption band regions for, 1 1 9t
reference spectrum for, 1 94{
H
Hair samples, collection of, 32
Herschel, William, 1
Hexane, as solvent, 29{
Hide glue, IR transmittance spectrum for,
1 0 1 {, 1 8 1{
High performance liquid chromatography
(HPLC), 1 7t
Honey, 1 80
IR transmittance spectrum of, 97{, 1 8 0{
HPLC. See High performance liquid
chromatography
Hydrocarbon stretching region
in polymer identification, 1 1 1
in spectral interpretation, 94
Hydrocarbons
aliphatic, absorption band frequencies of,
95t, 95-96, 96{
aromatic, absorption band frequencies of,
95t, 96, 97{
Hydrocerussite, absorption bands for, 1 1 7
Hydrogen
Bohr's atomic model for, 7{
emission spectrum of, 7
Hydroxyl, absorption band frequencies of,
95t, 96
Hypodermic needle, for cross section
removal, 33
Indigo, reference spectrum for, 1 97{
Inductive coupled plasma (ICP), 1 7t
Infiltration, of paint cross section samples,
35-37
prevention methods, 37
Infrared radiation
definition of, 1
discovery of, 1
molecular transitions affected by, 8
Infrared spectra, 5{, 83
absorption bands observed in, 1 1
attributes of, 82-83
detector response, 12{, 12-13
good-quality, requirements for, 87-9 1 , 88t
interpretation of. See Spectral
interpretation
plotting formats for, 84{, 84-86
reference collections of, 9 1 -92
regions in, 1 3-14
Infrared spectroscopy
applications of, 1 3 0-1 34, 1 7 1 . See also
Case studies
compared with other analysis
techniques, 1 7t
history of, 1-2, 3{
methods of, 43-80
microspectroscopy, 43, 68-79
optimal sample thickness for, 41
reflection analysis, 43, 60-68
transmission analysis, 43, 45-60
units used in, 6
vibrational transitions in, 1 0
Inorganic substances
in art objects, 1 7
chemical analysis methods for, 1 8t
contaminants, 23
separation of organic substances from, 31
Instrument configuration, 86-87
Intensity
of absorption bands, 83
and concentration of absorbing mole
cules, 85, 122-123
and dipole moment, 122
in quantitative analysis, 1 2 1
o f spectrum, a s quality check, 88t, 89-90
Interference fringes
compression/diamond cells and, 76
free film samples and, 56, 57{
Internal reflection, 60{, 65
Internal reflection spectroscopy (IRS), 60,
65-68, 66{. See also Attenuated
total reflection
applications of, 65-66
elements for, 66
introduction of, 60
for liquid analysis, 51
sample preparation for, 67, 67{
spectral alterations due to, 6 1 t
IR. See Infrared
Iron oxide pigments, mid-IR absorption band
regions for, 1 1 9t
IRS. See Internal reflection spectroscopy
IRIlS microspectrophotometer, 69, 70{, 136
Isinglass, reference spectrum for, 1 8 1{
Italian masters
binders used by, infrared analysis of,
152-155
ultramarine pigments used by, infrared
analysis of, 1 34-138, 1 35{, 1 36{
Ivory black, IR transmittance spectrum
for, 1 3 6{
Ivory, spectral identification of, 1 0 8
J. Paul Getty Museum, Roentgen desk at,
infrared analysis of varnish on,
144-148, 147{
]acquinot, P., 2
]CAMP.DX format, 93
K
Kaolin, IR transmittance spectrum for,
1 1 5{, 1 95{
Ketones, absorption band frequencies for,
96-97, 98{
Klucel F
IR transmittance spectrum for, 1 1 O{
spectral identification of, 109
Kramers-Kronig transformation, 63
KRS-5
infrared transmission characteristics of, 48t
as IRS element, 66
Kubelka-Munk function, in diffuse reflection
analysis, 63, 65
l
Lab-Calc, 93
Lacquers
accelerated aging studies of, 1 3 3
chemical analysis methods for, 1 8t
spectral identification of, 1 04
233
Index
Lapis lazuli, 1 3 4
IR transmittance spectra for, 1 3 7(
sources of, 1 37-1 3 8
Lattice structure, o f pigments, 1 1 4
Linear mapping microspectroscopy, 77, 77(
Linseed oil, IR transmittance spectrum for,
1 0 1 (, 1 85(
Liquid(s)
IR analysis methods for, 45t
reflection analysis of
diffuse, 64
internal, 67
sample collection and preparation proce
dures for, 25 t, 25-26
transmission analysis of, 50-51
Liquid cells, 5 1 , 5 1 (
Liquid nitrogen, adding t o sample before
grinding, 54
Liquid water, vibrational transitions of, 9(
M
Madder, reference spectrum for, 200(
(Mantegna), ultramarine
particles in, infrared analysis
of, 1 3 5(, 1 35-1 3 8
Malachite
absorption bands for, 1 1 6, 1 1 6t, 1 1 7
I R transmittance spectrum for,
Madonna with Child
1 1 5(, 1 99(
mid-IR absorption band regions for, 1 1 9t
Mallery, Garrick, 1 4 1
Mantegna, Andrea, 1 5 2
binders used by, infrared analysis of,
1 52-1 5 5
ultramarine particles in paintings of,
infrared analysis of, 1 35(,
37-41
and micro spectroscopic analysis, 76
oblique sectioning, 40-4 1 , 4 1 (
optimal embedment for, 35, 3 9 , 39(
orientation of sample, 39-40, 40(
problem solving, 4 1
trapezoid tip for, 3 9 , 40(
Microwave radiation, 4, 5(
Mid-infrared (MIR) region, 1 3-14
of pigments, 1 1 9t
Mineral oil, mixture of particles with, 57
Mineral wax, reference spectrum for, 1 8 3(
MIR region. See Mid-infrared region
Mixture(s)
resolution enhancement methods for, 125
separation of
by pyrolysis, 3 1-32, 32(
by solvent extractions, 29-3 1 , 30(, 3 1(
spectral identification of,
120-1 2 1 , 1 2 1 (
Molar absorptivity, 1 2 2
Molecular mapping, 77(, 77-79, 78(, 79(
Molecular transitions, 8
prediction of, degrees of freedom and,
8-10
MoMA. See Museum of Modern Art,
New York
Mortars, chemical analysis methods for, 1 8t
Muggli, Robert
2
Multiplex advantage, discovery of, 2
Museum of Fine Arts, Houston, Neoclassical
armchair at, infrared analysis of
paint on, 1 4 8-152, 149(
Museum of Modern Art, New York, cellulose
nitrate sculptures at, deteriora
tion studies of, 1 64-165
Z.,
1 35-1 3 8
Mapping microspectroscopy, 77-79
applications of, 1 3 2
area, 7 7 , 78(
case study of, 152-155
contour, 78, 79(
limitations of, 79, 1 54-155
linear, 77, 77(
Masonry, chemical analysis methods for,
Mastic, 1 8 9
I R absorbance spectrum for, 105(
IR transmittance spectrum for, 1 0 1 (,
mapping, 77(, 77-79, 78(, 79(
applications of, 1 32
case study of, 152-155
particle analysis, 70-72, 72(
resolution limit achievable in, 74
sample thickness and, 74-75, 75(
Microtoming, of cross section samples,
1 8t
1 06(, 1 8 9(
Mathematical manipulations of spectra,
1 24-127
resolution enhancement methods,
1 25-1 27
subtraction techniques, 124-125
Mercury-cadmium-telluride (MCT) detectors,
69, 8 6 , 1 3 6
Metals, chemical analysis methods for, 1 8 t
Michelson, Albert, 1
Microcrystalline wax, reference spectrum
for, 1 83(
Micropellet(s), 52
preparation of, 55
Micropellet die and holder, 53(
Microscopes, coupling with IR spectropho
tometer, 2, 6 8 , 6 9
Microspectrophotometer, 6 8
accessories for, 79
capabilities of, 69-70
design of, 69
IRpS, 69, 70(, 1 3 6
Microspectroscopy, 43, 68-79
aperture selection in, 7 1 , 72, 72(, 76
applications of, 68-69
cross section analysis, 72(, 76-79, 77(
diffraction in, 73-74, 75(
fiber analysis, 72(, 72-74
N
Native American ceramic pots, creosote lac
resin used in, infrared analysis
of, 1 3 8-1 4 1 , 140(
Natural materials. See Organic substances
Near-infrared (NIR) region, 1 3
Neoclassical armchair (Museum o f Fine Arts,
Houston), infrared analysis of
paint on, 1 4 8-152, 149(
Newton, Isaac, and internal reflection, 65
NIR region. See Near-infrared region
Nitric acid, as solvent, 30
Nitrogen, liquid, adding to sample before
grinding, 54
Noise, spectrum
as quality check, 8 8 t, 8 8-89
smoothing methods for, 8 9 , 90(
Nujol, mixture of particles with, 5 7
Nylon
IR transmittance spectrum of, 1 1 O(
spectral identification of, 1 0 9
o
OH-NH region
in polymer identification, 1 1 1
in spectral interpretation, 9 3
Oil(s)
IR transmittance spectra for, 1 0 1 (,
1 85(-1 8 6(
spectral identification of, 1 02-103
Oil mull, dispersion of particles in, 57
Olin, Jacqueline, 130
Optical microscope, coupling with IR
spectrometer, 2
Organic substances
in art objects, 1 7-1 8
chemical analysis methods for, 1 8t
contaminants, 23
separation from inorganic matrix, 3 1
spectral identification of, 1 00-108, 102(
Overtones, 9, 1 1
p
Paint(s)
chemical analysis methods for, 1 8t, 1 8-1 9
Chumash Indian, infrared analysis of,
1 4 1 - 1 44, 143(, 1 44(, 145(
cross section samples of, 33-34
embedding of, 34t, 34-37, 36(, 37(
infiltration of, 35-37
microtoming of, 37-41
reflection versus transmission analysis
of, 1 4 8-152
infrared analysis of, 120, 1 22(, 1 30-1 3 1
of Italian masters, infrared analysis of,
1 34-1 3 8 , 1 35(, 1 36(
on Neoclassical armchair, infrared
analysis of, 1 4 8-1 52, 1 49(,
1 50(, 1 5 1(
Paraffin
for embedding and microtoming of paint
cross sections, 34t
IR transmittance spectrum of, 96(
Parchment, ancient preparation techniques
for, 1 6 7
Particle, IR microspectroscopic analysis of,
70-72, 72(
Parylene, oxidation of, infrared analysis of,
1 59-1 63, 1 6 1(, 1 62t
Patinas
chemical analysis methods for, 1 8 t
infrared analysis of, 1 32
Pelco silicone rubber molds, for embedding, 35
Pellet(s)
in infrared transmission analysis, 52-54
numbered grid scratched into, 7 1 , 71 (
preparation of, 54-55
Pellet die, 53(, 54-55
Pellet holder, 53(
Percent transmittance, 12, 12(
Photomicrographs, 24
Phthalocyanine blue, reference spectrum for,
1 9 7(
Pigments. See also specific pigment
chemical analysis methods for, 1 8 t
infrared analysis of, case study, 1 34-1 3 8 ,
1 35(, 1 36(
infrared transmittance spectra for,
1 1 5(,
1 94(-200(
mid-IR absorption band regions for, 1 1 9 t
in paint analysis, 1 2 0
spectral identification of, 1 1 3-120
Pine resin, reference spectrum for, 1 8 7(
Plaster
absorption bands for, 1 1 7
chemical analysis methods for, 1 8 t
I R transmittance spectrum of, 1 1 5(, 1 95(
Plastic containers, for sample storage, 22
Plastics
chemical analysis methods for, 1 8 t
infrared analysis of, 1 63-165
Plotting formats, 84(, 84-86
Polarized light microscopy (PLM), 1 7t
Polishing
of infrared windows, 47-48
of IRS elements, 66
Polyamide, 1 9 3
IR transmittance spectrum of, 1 1 0(, 1 93(
Index
234
Polycyclohexanone, 193
IR transmittance spectrum of, 1 1 0(, 1 93(
spectral identification of, 1 0 9
Polyester, 1 9 1
absorption bands for, 3 7
embedding with, 34-35
for paint cross sections, 34t, 36, 37(
IR transmittance spectrum of, 98 (, 1 9 1(
Polyethylene
infrared transmission characteristics
of, 48t
infrared transmittance spectrum of, 1 1 0(
spectral identification of, 1 0 9
Polymer(s)
characterization process for, 1 1 0-1 1 3
chemical analysis methods for, 1 8t
reference spectra for, 1 9 0(-1 93(
spectral identification of, 1 0 9- 1 1 3 , 1 1 1(
Polystyrene
free film of, interference fringe pattern
obtained from, 57(
IR transmittance spectrum for, 97(
Polyvinyl acetate (PVAC), reference spectrum
for, 1 92(
Poppyseed oil, reference spectrum for, 1 85(
Potassium bromide
for elimination of interference fringes, 76
infrared transmission characteristics of,
importance of, 1 2 8
and visual pattern recognition procedure,
9 1 -92
Reflection, 46(
types of, 60(
Reflection analysis, 43, 60-68
comparison of methods, 44(, 6 1 t, 6 1 (
diffuse reflection spectroscopy (DRIFTS),
60, 63-65
internal reflection spectroscopy (IRS),
IR microspectrophotometer and, 70
reflection-absorption (R-A), 63
spectral alterations due to, 61 t
specular reflection, 62-63
of stone deterioration, 1 3 3
versus transmission analysis, case study
of, 1 4 8-1 52
Reflection-absorption (R-A), 63
spectral alterations due to, 6 1 t
Refraction, 46(
Refractive index values, 4 8 t
Residues, chemical analysis methods for, 1 8t
Resin(s)
accelerated aging studies of, 1 3 3
i n furniture surface treatment, infrared
analysis of, 144-148, 1 4 7(
infrared analysis of, case study,
1 3 8-1 4 1 , 140(
46, 48t, 49(
for pellet pressing, 54
Potassium chloride, infrared transmission
characteristics of, 4 8 t
Powder samples
internal reflection analysis of, 67
preparation of, 64
Presentation in the Temple (Mantegna),
ultramarine particles in,
infrared analysis of, 1 3 5(,
IR absorbance spectra for, 1 05(
IR transmittance spectra for, 1 0 1 (,
spectral identification of, 1 03-107, 1 07(
Resolution enhancement methods, 125-127
Reststrahlen bands, 62
Rice starch, reference spectrum for, 1 80(
Rock art, Chumash Indian, infrared
analysis of, 1 4 1 - 1 44,
143(, 1 44(, 145(
71
Roentgen, David, 145
Roentgen desk (J. Paul Getty Museum),
infrared analysis of varnish on,
1 0 1 (, 143(,
Rosin, IR transmittance spectrum for,
Pressed-pellet technique for IR analysis,
52-55
144-148, 147(
106(, 1 86(
1 8 1(-1 8 3(
spectral identification of, 1 0 8 , 142
Prussian blue
IR transmittance spectrum for, 1 3 6(,
mid-IR absorption band regions
for, 1 1 9t
Pulverizing of samples, 54
PVAC. See Polyvinyl acetate
Pyrolysis, mixture separation by, 3 1 -32,
Q
R
1 06(,
1 8 6(-1 90(
1 35-1 3 8 , 1 36(
Probe, in IR microspectroscopy,
Proteins
IR transmittance spectra for,
60,
65-68
1 98(
Rotary microtomes, 37-38, 3 8(, 39(
Rotational transitions, 8
degrees of freedom corresponding to,
9,
1 0(, l O t
energy transition levels for,
of water vapor, 9(
Rutherford, Ernest, 7
9(
32(
S
Qualitative analysis, 87-99
determination of spectral quality,
8 7-9 1 , 8 8 t
Quantitative analysis, 1 2 1 -124
Quartz, infrared transmission characteristics
of, 48t
Salts
chemical analysis methods for, 1 8 t
for elimination of interference fringes, 76
Sample blank, 23
Sample(s)/sampling. See also specific type
background information, 1 9
collection and preparation procedures,
24-4 1 , 25t
R-A. See Reflection-absorption
Radiation. See Electromagnetic radiation
Radio frequency radiation, 4, 5(
Rayleigh, Lord, 1
Razor blade, microscalpel made from, 2 1 , 2 1 (
Red pigments
mid-IR absorption band regions for, 1 1 9t
reference spectra for, 200(
Reference spectra, 1 78-200
on artists' colorants, 1 1 3
collections of, 9 1 -92, 1 09, 1 72-177
computer libraries search programs for,
92-93
concentration of, determination
of, 1 2 3
contamination of, avoidance of,
definition of, 1 6
design, 1 7- 1 9
documentation, 2 1 -22, 2 4 , 7 1
flattening of, 32-33, 5 8 , 75-76
freestanding, 56
grinding/pulverizing of, 54
implementation, 20-23
location, 1 9-20
representative, 20
storage, 22-23
with swabs, 26-27, 27(
23
thickness of, effects in IR microspec
troscopy, 74-75, 75(
tools for, 20-2 1 , 2 1 (
Sandarac, 1 8 9
I R absorbance spectrum for, 105(
IR transmittance spectrum for, 106(, 1 8 9(
Sapphire, infrared transmission characteristics
of, 4 8 t
Scaled absorbance subtraction, 1 2 4
Scalpels, 2 1 , 2 1 (
for cross section removal, 3 3
for liquid sampling, 2 6
proper use of, 2 8 , 2 8 (
Scattering, reduction of, 56
Selection rules, for IR absorptions, 1 1
Semiquantitative analysis, 1 2 1-122
Shellac, 1 07, 138, 1 9 0
I R absorbance spectrum for, 1 05(
IR transmittance spectrum for, 1 0 1 (,
1 06(, 1 90(
Signal-to-noise ratio, of spectrum, 8 8-89
Silica/silicates
absorption bands for, 1 1 5(, 1 1 6t,
1 1 7-1 1 8
I R transmittance spectrum for, 1 1 5(, 1 96(
Silicon, as IRS element, 66
Silicon carbide paper, for sample collection, 64
Silver chloride
infrared windows, 47, 4 8t
as IRS element, 6 6
Skeletal (torsional) vibration, 1 0-1 1
Slide sandwich, 22(, 22-23
Smoothing methods, to decrease spectrum
noise, 89, 90(
Sodium chloride
for elimination of interference fringes, 76
infrared transmission characteristics of,
46, 4 8t
Sodium hydroxide, as solvent, 30
Solids
cross section. See Cross section samples
fibrous. See Fibers
IR analysis methods for, 45t
reflection analysis of
diffuse, 64-65
internal, 67
sample collection and preparation proce
dures, 25t, 28-41
solvent-soluble, 29-3 1
transmission analysis of, 52-60
film techniques, 56-59
pressed-pellet technique, 52-55
Solubility schematic, 29(
Solution(s)
diffuse reflection analysis of, 64
film preparation from, 56-57
internal reflection analysis of, 67
Solution spectroscopy, 50-51
Solvent(s), chemical analysis methods for, 1 8t
Solvent extractions, mixture separation by,
29-3 1 , 30(, 3 1(, 1 20
Spectral identification, 87, 87(
of inorganic materials, 1 1 3-120
of mixtures, 120-1 2 1 , 1 2 1 (
of organic materials, 100-108, 1 02(
of synthetic resins (polymers),
1 09-1 1 3, 1 1 1 (
Spectral interpretation
absorption band attributes and, 82-83
computer libraries search programs and,
92-93
correlation charts and, 99, 99(
functional groups in, 93-95
identification scheme for, 87(
instrument configuration, 86-87
mathematical manipulations in, 124-127
235
Index
plotting formats and, 84(, 84-86
qualitative analysis and, 87-99
quantitative analysis and, 1 21-124
spectra-structure correlations in, 95-98
visual comparison and, 9 1 -92
Spectral quality, determination of,
87-9 1, 88t
Spectral subtraction, 124-125, 126(
Spectra-Tech, 2
IRIlS microprobe, 1 3 6
Spectroscopy
definition of, 4
infrared. See Infrared spectroscopy
Spectrum (spectra), 7
electromagnetic, 4, 5 (
infrared. See Infrared spectra
quality of, determination of, 87-9 1 , 88t
Specular reflection, 62-63
as distortion in reflection-absorption
experiment, 63
IR spectra of Acryloid B-72 collected by,
44(, 6 1 (
mapping studies and, 7 9
spectral alterations due to, 6 1 t
Starch, reference spectrum for, 180(
Steel knives, for rotary microtomes,
37, 38(
Stereo microscope, in IR microspectroscopic
analysis, 70-7 1 , 76
Stone(s)
chemical analysis methods for, 1 8t
weathering of, infrared analysis of, 1 3 3
Storage
of infrared windows, 49
of samples, 22-23
Stretching vibration, 1 0
Subtraction techniques, for spectral analysis,
1 24-125, 126(
Sugars, reference spectra for, 1 79(-1 80(
Sulfates, absorption bands for, 1 1 5(, 1 1 6t,
117
Sulfuric acid, as solvent, 30
Sulfuryl fluoride (Vikane), infrared analysis
of, 1 55-1 59, 1 5 7(
Swabs, sampling with, 26-27, 27(
Synthetic resins (polymers)
infrared analysis of, 1 3 1
reference spectra for, 1 90(-1 93(
spectral identification of, 1 09-1 13, 1 1 1 (
T
Teflon, infrared transmission characteristics
of, 48t
Thallium iodide bromide, infrared transmission characteristics of, 48t
Thin-layer chromatography (TLC), 1 7t
Torque wrench, 67(
Torsional (skeletal) vibration, 1 0-1 1
Tragacanth, spectral identification of,
1 08, 1 79(
Translational transition, 8
degrees of freedom corresponding to, 9,
1 0(, lOt
Transmission, 46(
in IR experiments, 1 3
Transmission analysis, 4 3 , 45-60
acceptance of, 80
advantages of, 45
film techniques for, 56-59
of gases, 50
IR spectra of Acryloid B-72 collected by,
44(, 6 1 (
o f liquids, 50-51
microspectroscopy and, 71
possible spectral anomalies with, 47t
pressed-pellet technique for, 52-55
versus reflection analysis, case study of,
148-152
of solids, 52-60
support materials used in, 46-49, 48t
Transmittance mode, for spectral display,
84(, 85
Tukey, John, 2
Tungsten knives, for rotary microtomes,
37, 38(
Tungsten needle, 20, 2 1 (
U
Ultramarine
mid-IR absorption band regions for, 1 1 9t
pigments, infrared analysis of, 134-1 38,
135(, 1 36(
reference spectrum for, 1 98(
Ultraviolet radiation, 4, 5(
Ultraviolet spectroscopy, units used in, 6
Unknown material, spectral identification of.
See Spectral identification
Urushi ( oriental lacquer), spectral
identification of, 1 04
UV. See Ultraviolet
V
Vapor-phase depletion measurements,
155-159
Variable-angle external reflection
accessory, 62(
Vegetable wax, reference spectrum for, 1 84(
Venus and Adonis (Titian), ultramarine parti
cles in, infrared analysis of,
1 34-138, 1 35(
Verdigris, reference spectrum for, 1 99(
Vibrational transitions, 8
degrees of freedom corresponding to,
9-10, 1 0(, lOt
energy transition levels for, 9(
in IR spectroscopy, 10
of lattice structure, 1 14
of liquid water, 9(
types of, 1 0-1 1
Vikane (sulfuryl fluoride), interaction with
solid materials, infrared analy
sis of, 1 55-1 59, 1 5 8(, 1 59(
Visible radiation, 4, 5(
Visible spectroscopy, units used in, 6
Visual pattern recognition procedure, 91-92
W
Walnut oil, reference spectrum for, 1 86(
Water
as solvent, 29(, 30
vibrational transitions of, 9(
Water of hydration, absorption bands for,
1 1 6, 1 1 6t
Water vapor
extraneous bands produced by,
88t, 90-91
rotational absorption bands for, 9(
Wave theory, of electromagnetic radiation,
4-6, 6(
Wavelength, 5, 6(
disadvantages of using, 6
Wavenumber, 5-6
advantages of using, 6
Wax(es)
IR transmittance spectra for, 101(,
1 83(-1 84(
spectral identification of, 1 00-102
White pigments
mid-IR absorption band regions for, 1 1 9t
reference spectra for, 1 94(-1 95(
Wick-Stick, 55
Window region
in polymer identification, 1 1 1-1 1 2
i n spectral interpretation, 9 4
Windows, infrared, 46-49
film analysis on, 56-58
materials for, 46-47, 48t
polishing of, 47-48
storage of, 49
thickness of, 47
Wood, chemical analysis methods for, 1 8t
x
yZ
X rays, 4, 5(
X-ray diffraction (XRD), 1 7t
X-ray fluorescence (XRF), 1 7t
Yellow, mid-IR absorption band regions
for, 1 1 9t
Zinc selenide
infrared transmission characteristics of, 48t
as IRS element, 66
About the Authors
Michele R. Derrick is a chemist and conservation scientist with more
than twenty years' experience analyzing and characterizing materials.
She graduated from Oklahoma State University in 1 9 7 9 with an M.S.
degree in analytical chemistry, then worked at the University of Arizona
Analytical Center. She next worked for twelve years as a conservation
scientist at the Getty Conservation Institute. Derrick currently has a
dual role as a consultant for the Museum of Fine Arts, Boston, and as
a chemist at a commercial analytical laboratory. Derrick has published
more than thirty articles in j ournals and proceedings. In 1 99 5 she
received the Kress Foundation conservation publication fellowship that
funded this volume. She currently holds a grant from the National
Center for Preservation Technology and Training to compile a database
on materials used in the production and conservation of historic and
artistic obj ects and sites.
Dusan Stulik graduated from Charles University in Prague with B.S. and
M.S. degrees in chemistry. He subsequently obtained a Ph.D. degree in
physics from the Czechoslovakia Academy of Sciences. He is currently
a senior scientist in the Scientific Program at the Getty Conservation
Institute, where his research focuses on the application of modern sci
entific methods to conservation science.
James M. Landry is a professor of chemistry and director of the Natural
Science Program at Loyola Maiymount University in Los Angeles. He
received his B.S. and M.S. degrees in chemistry from Xavier University
in Cincinnati. He then obtained his Ph.D. degree in inorganic chemistry
from Miami University of Ohio, specializing in molecular spectroscopy.
His research interests include projects in IR microspectroscopy and gas
chromatography-mass spectrometry. He has recently been involved in
developing a formulation and application process for a novel coating that
blocks the transmission of heat through a variety of materials. He has
been involved in the Los Angeles Collaborative for Teacher Excellence
( LACTE) , an association of ten colleges funded by the National Science
Foundation that works to improve the preparation of future K-1 2
science and math teachers.
ISBN 0 - 89236-469-6
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