Preparation and Applications of Fluorinated Graphenes
Yasser AhmadC
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The present review focuses on the numerous routes for the preparation of fluorinated graphene (FG) according to the starting materials. Two strategies are considered: (i) addition of fluorine atoms on graphenes of various nature and quality and (ii) exfoliation of graphite fluoride. Chemical bonding in fluorinated graphene, related properties and a selection of applications for lubrication, energy storage, and gas sensing will then be discussed.
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Chemistry, properties, and applications of fluorographene
Applied Materials Today, 2017
Fluorographene, formally a two-dimensional stoichiometric graphene derivative, attracted remarkable attention of the scientific community due to its extraordinary physical and chemical properties. We overview the strategies for the preparation of fluorinated graphene derivatives, based on top-down and bottom-up approaches. The physical and chemical properties of fluorographene, which is considered as one of the thinnest insulators with a wide electronic band gap, are presented. Special attention is paid to the rapidly developing chemistry of fluorographene, which was advanced in the last few years. The unusually high reactivity of fluorographene, which can be chemically considered perfluorinated hydrocarbon, enables facile and scalable access to a wide portfolio of graphene derivatives, such as graphene acid, cyanographene and allyl-graphene. Finally, we summarize the so far reported applications of fluorographene and fluorinated graphenes, spanning from sensing and bioimaging to separation, electronics and energy technologies.
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Fluorographene (FG) is a two-dimensional graphene derivative with promising application potential; however, its reactivity is not understood. We have systematically explored its reactivity in vacuum and polar environments. The C−F bond dissociation energies for homo- and heterolytic cleavage are above 100 kcal/mol, but the barrier of SN2 substitution is significantly lower. For example, the experimentally determined activation barrier of the FG reaction with NaOH in acetone equals 14 ± 5 kcal/mol. The considerable reactivity of FG indicates that it is a viable precursor for the synthesis of graphene derivatives and cannot be regarded as a chemical counterpart of Teflon.
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We studied a possibility of reduction of the surface of graphite fluoride obtained by fluorination of highly oriented pyrolytic graphite (HOPG) by a gaseous mixture of BrF3 and Br2. X-ray diffraction (XRD) revealed a layered structure of the fluorinated product being a second-stage intercalate due to a presence of bromine molecules between the fluorinated graphite layers. Scanning tunneling microscopy and spectroscopy showed that the “old” surface of graphite fluoride (exposed to the ambient air) has the graphite-like structure, while the fresh cleaved surface is non-conductive. Therefore, the outer layers of graphite fluoride can be reduced by water present in the laboratory atmosphere. The sample was treated by H2O vapor to confirm that. The reduction was controlled by Raman spectroscopy using intensity of the 1360 and 1580 cm−1 bands. The energy dependent photoelectron spectroscopy was used for estimation of thickness of the reduction layer, which was found, does not exceed 2–3 graphite layers. The obtained results indicate the possibility of synthesis of graphene layers on dielectric fluorinated graphite matrix.
Graphene Fluoride: A Stable Stoichiometric Graphene Derivative and its Chemical Conversion to Graphene
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Stoichoimetric graphene fluoride monolayers are obtained in a single step by the liquid-phase exfoliation of graphite fluoride with sulfolane. Comparative quantum-mechanical calculations reveal that graphene fluoride is the most thermodynamically stable of five studied hypothetical graphene derivatives; graphane, graphene fluoride, bromide, chloride, and iodide. The graphene fluoride is transformed into graphene via graphene iodide, a spontaneously decomposing intermediate. The calculated bandgaps of graphene halides vary from zero for graphene bromide to 3.1 eV for graphene fluoride. It is possible to design the electronic properties of such two-dimensional crystals.
Reactivity of Fluorographene: A Facile Way toward Graphene Derivatives
The Journal of Physical Chemistry Letters, 2015
Fluorographene (FG) is a two-dimensional graphene derivative with promising application potential; however, its reactivity is not understood. We have systematically explored its reactivity in vacuum and polar environments. The C−F bond dissociation energies for homo-and heterolytic cleavage are above 100 kcal/mol, but the barrier of S N 2 substitution is significantly lower. For example, the experimentally determined activation barrier of the FG reaction with NaOH in acetone equals 14 ± 5 kcal/mol. The considerable reactivity of FG indicates that it is a viable precursor for the synthesis of graphene derivatives and cannot be regarded as a chemical counterpart of Teflon.
Flexibility of Fluorinated Graphene-Based Materials
Materials
The resistivity of different films and structures containing fluorinated graphene (FG) flakes and chemical vapor deposition (CVD)-grown graphene of various fluorination degrees under tensile and compressive strains due to bending deformations was studied. Graphene and multilayer graphene films grown by means of the chemical vapor deposition (CVD) method were transferred onto the flexible substrate by laminating and were subjected to fluorination. They demonstrated a weak fluorination degree (F/C lower 20%). Compressive strains led to a strong (one-two orders of magnitude) decrease in the resistivity in both cases, which was most likely connected with the formation of additional conductive paths through fluorinated graphene. Tensile strain up to 3% caused by the bending of both types of CVD-grown FG led to a constant value of the resistivity or to an irreversible increase in the resistivity under repeated strain cycles. FG films created from the suspension of the fluorinated graphene...
C
Journal of
Carbon Research
Review
Preparation and Applications of Fluorinated Graphenes
Yasser Ahmad 1 , Nicolas Batisse 2 , Xianjue Chen 3
1
2
3
*
and Marc Dubois 2, *
Fahad Bin Sultan University, P.O. Box 15700, Tabuk 71454, Saudi Arabia; [email protected]
Centre National de la Recherche Scientifique, SIGMA Clermont, ICCF, Université Clermont Auvergne,
F-63000 Clermont-Ferrand, France; [email protected]
School of Chemistry, The University of New South Wales, Sydney, NSW 2052, Australia;
[email protected]
Correspondence: [email protected]
Abstract: The present review focuses on the numerous routes for the preparation of fluorinated
graphene (FG) according to the starting materials. Two strategies are considered: (i) addition of
fluorine atoms on graphenes of various nature and quality and (ii) exfoliation of graphite fluoride.
Chemical bonding in fluorinated graphene, related properties and a selection of applications for
lubrication, energy storage, and gas sensing will then be discussed.
Keywords: graphene; fluorination; fluorinated graphene; lubrication; energy storage; gas sensing
1. Introduction
Citation: Ahmad, Y.; Batisse, N.;
Chen, X.; Dubois, M. Preparation and
Applications of Fluorinated
Graphenes. C 2021, 7, 20. https://
doi.org/10.3390/c7010020
Received: 14 December 2020
Accepted: 27 January 2021
Published: 7 February 2021
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Attribution (CC BY) license (https://
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4.0/).
Fluorination is one of the most used chemical treatments to add one or several properties to carbonaceous materials. The most evident quality is hydrophobicity because of the
high electronegativity of fluorine element; once bonded to carbon atom, the high difference in electronegativity between the two elements results in high negative partial charge
on F atom. Fluorination may be used to change the surface chemistry from hydrophilic
to hydrophobic character [1–3]. Combination of hydrophobic surface due to C–F bonds
and micro-texturing of the surface results in superhydrophobicity [4]. This occurs when
polar oxygenated groups (C–O, COOH, COH, etc.) are converted into C–F bonds. C–F
bonds are electrochemically active in primary lithium batteries and capacities as high as
865 mAh/g may be reached when the highest fluorine content is considered, i.e., with CF1
composition [5–7]. Presence of fluorine atoms between carbon sheets in covalent graphite
intercalation compounds F-GICs decreases both the energy needed for sheet cleavage and
the friction energy, i.e., low friction coefficients are obtained for graphite fluorides, and in a
general way, for fluorinated graphitized (nano)carbons. The low friction coefficients are
achieved for medium and high fluorine content, e.g., CF0.20 for fluorinated nanofibers [8].
C–F bonds may favorably interact with some gases, such as ammonia, and fluorinated
carbons with high specific surface area (SSA) appear to be promising active materials for
gas sensing. Because of the numerous applications in energy storage, solid lubricant, gas
sensing, but also as fillers in (nano)composites with hydrophobic polymer matrix because
the differences between the surface energies of fillers and polymer are decreased, the
fluorination of (nano)carbons has been extensively studied [5,9–17]. The main parameters
that affect the reaction are well known: (i) the higher the graphitization degree, the higher
the fluorination temperature; graphite is fluorinated at temperature higher than 350 ◦ C
in pure molecular fluorine F2 and up to 600–650 ◦ C to form the (CF)n structural type
with FCF/FCF stacking sequence ((C2 F)n ; FCCF/FCCF stacking is formed at intermediate
temperature range of 350–450 ◦ C). (ii) because fluorination is a heterogeneous gas/solid
reaction, materials with high SSA exhibit high reactivity towards fluorinating agents (FAs)
such as F2 but also gaseous xenon difluoride XeF2 , BF3 , IF5 , ClF3 , etc. When the carbon
lattice exhibits a curvature, as for fullerenes and derivatives such as nanotubes, the reactivity towards FA is also increased. Graphene is a single-layer sheet of carbon atoms with
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a high specific surface area, and the reactivity upon fluorination is expected to be very
high. Molecular fluorine appears then to be a too strong oxidant to be used for the covalent
functionalization of monolayer graphene. Because of the high reactivity, perfluorination of
the sheet edges (saturation with formation of CF2 and CF3 groups) and decomposition in
CF4 , C2 F6 , and other short fluorocarbon fragments may occur. If some solid fluorocarbon
sheets are still maintained they are highly defected and applicative properties suffer from
this degradation. Molecular fluorine must be diluted with an inert medium to avoid the
decomposition or other FAs must be considered. The present review focuses only on fluorinated graphene (FG) without, of with a few other heteroatoms. Oxyfluorinated graphene
is not under consideration. Traces of oxygen may still remain after fluorination when the
precursor is graphite oxide or graphene oxide (GO) even reduced.
Whereas single layer graphene has a striking combination of unique properties [18–20],
such as an exceptionally high charge carrier mobility and conductivity [21,22], while retaining excellent mechanical flexibility [23], and high optical transparency [24,25], graphene
becomes a wide gap semiconductor when functionalized with fluorine [26–29]. The band
gap of 4.2 eV is expected for 100% functionalization with fluorine through theoretical
predictions (3.8 eV with hydrogen) [30,31]. With F atom addition saturated at C4 F for onesided fluorination, the calculated band gap of optically transparent FG is 2.93 eV [22,32].
This single atomic layer holds the promise for future bendable and transparent all-graphene
electronics, i.e., devices where insulating graphene is used as a host material in which
conductive and semiconductive graphene channels can be opened. Chemical isolation was
achieved by exposing the unmasked graphene nanoribbons to xenon difluoride XeF2 gas
to convert it to insulating fluorographene [33].
Chemical bonding in fluorinated graphene and related properties will be discussed in
the present review after presenting the various synthesis routes. A selection of applications
will also be discussed: lubrication, energy storage, electronic device, and gas sensing.
At the present time, the methods for preparing fluorinated graphene of general
composition Cx Fy and fluorographene with CF1 stoichiometry could be mainly divided
into two groups regarding the starting material. Figure 1 summarizes the two strategies and
their sub-divisions. On one hand, one method involves fluorination of graphene or reduced
graphene oxide using various fluorinating agents including F2 , HF, XeF2 , decomposition
of fluoropolymers [34], or utilizing plasma such as CF4 and SF6 [35]. On the other hand,
exfoliation of graphite fluorides appears as a top-down strategy [34,36].
Figure 1. The two strategies for preparing fluorinated graphene (FG) of general composition Cx Fy and fluorographene with
CF1 stoichiometry.
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2. The Conventional Direct Fluorination with Molecular Fluorine
A few studies have reported the use of diluted molecular fluorine and only on reduced
graphene oxide (GO) in the form of multilayer. The presence of several graphene layers
allows the fluorination to be favored in comparison with decomposition. Covalent grafting
and decomposition always compete whatever the carbon lattice. Negligible for the case of
graphite, decomposition dominates for graphene monolayer. As first examples, fluorinated
graphenes were prepared from graphene oxide reduced in microwave plasma. N2 /F2 mixture with 20% vol./vol. of F2 at pressure of 3 bar has been used [37,38], with 70 kPa F2 /N2
mixed gas (F2 content is 10%) [39] or with F2 /N2 (50 kPa) in the 180–210 ◦ C range [40]. The
work using F2 /N2 (50 kPa) at 200 ◦ C on GO evidences the role of oxygenated groups that
facilitate the fluorination [41]. Nevertheless, a few oxygenated groups were still present in
the final product. The same defects in FG are present with diethylaminosulfur trifuoride
(DAST); this commercially available liquid fluorinating agent allows the chemical transformation of GO to FG under mild conditions [42]. The fluorine content can be easily tailored
up to 23 at.% by altering the reaction medium.
Graphene with a small amount of oxygen (8 at.%) typical of graphene samples prepared by chemical exfoliation was fluorinated with 20/80 vol.% F2 /N2 at 2 bars for 5 h and
24 h at room temperature. Oxygen content remained approximately constant whatever the
fluorination content [43].
As graphite oxide, graphene oxide (GO) exhibits the following functional groups:
epoxides COC, COH, sp2 carbon in oxidized environment, and carboxyl groups COOH;
their relative amounts differ according to the synthesis route Hummers; Hummers modified improved synthesis [44]. The completion of the conversion of oxygenated groups into
fluorinated groups may be questioned. A recent work on direct fluorination using F2 gas
at room temperature gives some information. The mild fluorination resulted in homogeneous fluorine dispersion when precursor was graphite oxide. Mild fluorination of GO for
duration in between 15 and 90 min results in a triphasic oxyfluoride/fluoride/graphite material, while longer fluorination duration (240 min) leads to a biphasic oxyfluoride/fluoride
material [45]. The decomposition temperature, higher than for raw GO, was related to the
presence of fluorinated groups with high thermal stability as seen with graphite fluorides.
The profile attested to a continuum of functions with superimposed thermal decompositions. The diversity of functions contained in the oxyfluoride was evidenced by solid
state NMR evidence. Chemical shifts are measured at 59, 87, 110, 138, and 165 ppm vs
TMS, respectively assigned to isotropic bands of functional groups COC, CF, CF2 , sp2 C,
and COOH. COH are missing because of their quasi-total conversion into C–F during the
fluorination. Fluorine atoms coexist with oxygen ones in fluorinated GO or fluorinated
graphene oxide.
3. Other Fluorinating Agents
Xenon difluoride XeF2 was often used because its reaction with graphene resulting
in any routes occurs at low temperature (from room temperature to 250 ◦ C) [46]. The
sublimation equilibrium between solid and gaseous XeF2 is used to generate the gas that
reacts with graphene. The amount of FA may be perfectly controlled contrary to gas
F2 . Several works used the XeF2 route either with chemical vapor deposition (CVD)grown graphene [47,48], with graphene films grown on Cu foils then transferred to either
silicon-on-insulator or SiO2 /Si substrates [29,32], with the graphene-on-Cu sample and
the Cu foil [49], or with graphene on SiC(0001) and then converted into quasi-freestanding
graphene by hydrogen intercalation [50].
The efficiency of XeF2 fluorination is changed by generating defects within the
graphene layer, e.g., by an oxygen plasma etcher [51]. Whereas the reactivity of the
single layer graphene is not significantly affected, the case of graphene bilayers is different;
either a decrease in the reactivity was reported for a small number of new defects or an
increase in reactivity was reported for a larger number of defects. This complex behavior
results from a balance between the increase in reactivity towards the FA for some defects,
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as expected, and stabilization of some parts of graphene (charge inhomogeneities) via
formation of more stable groups.
SF6 may be used as the etching gas, as exemplified on chemical CVD-grown graphene
in a reactive ion etching [52]. To avoid adverse etching with SF6 plasma of graphene
(deposited on the Ge (110) substrate by atmospheric pressure chemical vapor deposition),
samples were placed upside-down on the pedestal in SF6 plasma environment [53].
In a two-step process, the first step consisted in the electrochemical exfoliation of highoriented pyrolytic graphite (HOPG) with its additional processing with ultrasound. The
fluorination of this suspension was proceeded in a weak (~3–7%) solution of hydrofluoric
acid [54]. The fluorination duration was adjusted to the initial sizes of graphene particles.
Low fluorine contents were achieved with this route, i.e., F/C atomic ratio lower or equal
to 0.23. With the same two-step strategy involving aqueous HF, chemical exfoliation may
be used to prepare the starting suspension [55]. Mechanical crushing of natural graphite,
dimethylformamide (DMF) intercalation, ultrasonic treatment intended for splitting the
intercalated particles, followed by centrifugation in order to remove non-split graphite
particles was then carried out to prepare the suspension before the fluorination.
A one-step hydrothermal process using HF (40 w.%) as the fluorination source has
been used to convert GO in aqueous dispersion [56]. During a hydrothermal process, the
fluorination and reduction processes of GO occurred simultaneously. In order to reduce
the surface energy of graphene nanoflake, fluorinated graphene nanoflake was prepared
by solvo-thermal reaction between GO and HF [57].
An alternative for the use of reactive fluorinating agents has been reported by Lee et al. [58].
Graphene has been selectively fluorinated by irradiating fluoropolymer-covered graphene
with a laser. The active fluorine radicals produced by photon-induced decomposition of
the fluoropolymer (CYTOP) reacted with the sp2 -hybrized carbons and C−F bonds were
formed. Because the reactive species are the same, atomic fluorine, FG from this route
exhibits similarities with the ones obtained with XeF2 .
Plasma technology allows the control of the fluorination whatever the graphene type.
Numerous parameters may be tailored for this aim, i.e., gas pressure in the chamber, power
for the plasma discharge ignition, exposure time. Different reactive gases may be used
for plasma fluorination, e.g., CF4 and SF6 , and then different fluorinated groups are then
introduced. Indeed, ions drive chemical reactions at the surface when reactive species
are present during irradiation. Using CF4 plasma treatment, adatom clustering occurs
but it can be avoided when higher kinetic energy is supplied to the ions [35]. Careful
attention must be paid to the interaction of the reactive gas with the graphene substrate.
Using SF6 plasma, the sulfur atoms tend to bond to bare copper areas (substrate) instead
of changing the graphene chemistry. Monolayer graphene grown by CVD using Cu foil
was treated with controllable SF6 plasma treatment and F content close to 25 at.% was then
achieved [59]. Such conditions result in the formation of covalent C−F bonds, which are
perpendicular to the basal plane of FG, as evidenced by angle-dependent near edge X-ray
absorption fine structure (NEXAFS).
4. Exfoliation of Graphite Fluoride
4.1. Mechanical
Mechanical exfoliation from a graphite fluoride appears to be an easy route to prepare
FG without drastic defluorination. Nevertheless, the quantities of high-quality few-layer
graphene are often low and lateral size of the layer is significantly decreased in comparison
with graphite fluoride granulometry. FG flakes may be obtained by mechanical cleavage
of graphite onto adequate substrate, e.g., SiO2 /p-doped Si substrate (which acts as a back
gate for electrical transport measurements). The homogeneity of the fluorine atoms distribution is of primary importance. As a matter of fact, when this distribution is highly
homogenous, the probability of producing fluorinated monolayer is high [27,28]. On the
contrary, when the dispersion is less homogenous, exfoliation efficiency appeared to be
lower and few layers of FG were then obtained [60]. Regarding the smaller radius and thus
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higher diffusion rate in the interlayer space of graphite of atomic F• released by XeF2 , this
FA must be favored for homogenous dispersion of F atoms in graphite fluoride precursor
and then the preparation of monolayer FG. The ability to use mechanical exfoliation to
control the fluorine content of graphene is promising for engineering different electronic
properties in graphene materials. The prepared FG provides evidence of the possibility
to tune the electronic transport properties of graphene mono-layers and multilayers by
functionalization with fluorine. For mono-layer samples, by increasing the fluorine content,
a transition from electronic transport through Mott variable range hopping (VRH) in two
dimensions to Efros–Shklovskii VRH has been evidenced. Multi-layer fluorinated graphene
with high concentration of fluorine shows two-dimensional Mott VRH transport, whereas
CF0.28 multi-layer flakes exhibit thermally activated transport through near neighbor hopping [27,28]. Another way to tune the electoral transport is electron beam irradiation [60];
the resistivity of insulating FG can be progressively decreased by several orders of magnitude simply (Figure 2). The electron-irradiated fluorinated graphene ultimately exhibited
the resistance per square of pristine graphene.
Figure 2. Nanopatterning of fluorinated graphene by electron beam irradiation (a) (adapted with permission from ref [60],
Copyright, 2011, American Chemical Society). The defluorination resulted in a decrease of both the interlayer distance and
the height from SiO2 substrate in atomic force microscopy (AFM) measurements (b). The surface resistance of FG connected
to Cu/Au plots (c) decreased according to the electron dose (d).
4.2. Thermal Exfoliation
Graphite fluorides of any type appear to be excellent precursors to formed multi-layer
graphene. Thanks to the presence of a high amount of fluorine atoms in covalent (CF)n , the
exfoliation of fluorinated graphite by a very fast thermal treatment has proved to be efficient.
Both exfoliation and restructuring of the graphitic regions occurred simultaneously during
the flash; conductive graphene with a low fluorine content was then prepared. Contrary to
GO, the reduction step to obtain pure graphene could be easier because of the low amount
of residual fluorinated groups. Another strategy involved semi-covalent graphite fluoride
–
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synthesized at room temperature thanks to a catalytic gaseous mixture, based on a thermal
shock induced by a flame [61]. The starting material exhibited a weakened covalence
(called also semi-covalent) for the C–F bonding that favored the exfoliation. Moreover,
residual catalysts such as IF5 , IF6 − , and IF7 , which were still intercalated after the room
temperature synthesis, acted also on the exfoliation because of their fast deintercalation
(Figure 3).
Figure 3. Schematic view of the thermal exfoliation of graphite fluoride containing semi-covalent (weakened covalence)
and covalent regions (reproduced/adapted with permission from ref [61], Copyright, 2014, Elsevier). Colors before and
after exfoliation (a), FTIR spectra of the gases involved into the reactor during the thermal shock (b) and TEM images (c) of
the resulting sample are also shown. The FTIR spectra were recorded as a function of the duration (3, 6, 9, and 12 min) after
the connection of the reactor to the measurement cell.
Graphite fluoride obtained with a two-step process, i.e., synthesis of a bromineintercalated graphite followed by long fluorination (14 days at room temperature with
10 vol.% solution of BrF3 in Br2 ) was thermally exfoliated with a fast increase of temperature
at 800 ◦ C [62]. It is to be noted that the reactive species are fluorine atoms released from
BrF3 . The resulting material consisted of flat particles with an average basal plane size of a
few microns and low concentration of defects. Residual bromine and fluorine species as
well as oxygen-containing groups were still present.
Using thermal treatments or microwave plasma exfoliation of GO in atmospheres containing SF6 , SF4 , and MoF6 as fluorinating agents, fluorographene was prepared. Process
with SF6 at 800 ◦ C results in the highest F content (4.25 at.%) [63].
4.3. In Liquid Media
Liquid-phase exfoliation of layered materials is a simple and versatile method for
preparing two-dimensional single- or few-layer materials in large quantities. Graphite
fluoride can be easily exfoliated under shear force that facilitates the intercalation of solvent
molecules into the interlayer galleries, weakening the van der Waals attraction between
two adjacent layers and resulting in an expanded interlayer distance and thus separation
of single- or few-layers in colloidal suspensions. The stability of the resulting graphene
fluoride strongly depends on the temperature used in the process, i.e., room temperature
treatment allows exfoliated graphene fluoride to retain its original chemical composition;
high temperature leads to partial decomposition despite a higher yield of single- or fewlayer. In addition, the use of intercalating molecules and reaction condition (time and
pressure) are important for facilitating the exfoliation process and the quality of product.
That said, the precise control over the size and thickness (number of layers) of graphene
fluoride is still challenging, which leads to a relatively poor selectivity of the exfoliation.
To date, exfoliation of single- or few-layer graphene fluoride from graphite fluoride using sonication in various liquid media has been reported, including sulfolane, isopropanol
Zbořil et al. prepared graphene fluoride using a one
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(IPA), ethanol, ionic liquids, N-methyl-2-pyrrolidone (NMP), dimethylformamide (DMF),
chloroform, acetonitrile, and aqueous solutions in the presence of surfactant. Zbořil et al.
prepared graphene fluoride using a one-step exfoliation process, which involved suspending graphite fluoride in sulfolane, followed by sonication [64]. It is found that the high
polarity of sulfolane is capable of stabilizing the exfoliated layers in the solution. The
product consisted of a large fraction of single layers, although multi-layers (2–4 nm in
thickness) were also observed. Cheng et al. [26] reported the exfoliation of fluorinated
HOPG crystals into thin sheets in IPA using sonication, which were deposited onto a TEM
grid for characterizing the structure of the fluorinated compounds. Similarly, graphene
fluoride was fabricated by sonicating graphite fluoride in IPA [65,66] or ethanol [67,68] at
room temperature. Chang et al. prepared a colloidal dispersion of single- and few-layer
graphene fluoride in ionic liquid (1-butyl-3-methylimidazolium bromide) using sonication
at room temperature [69]. The formation of graphene fluoride is attributed to surfaceenergy matching between the ionic liquid and the graphene sheets in graphite fluoride.
As a consequence, ionic liquid molecules can intercalate into the layers and absorb on the
surface, leading to a significant decrease in van der Waals interaction between neighboring
layers. The exfoliated graphene fluoride was 1–4 nm in thickness and 2–10 µm in lateral
size. The exfoliation of graphene fluoride in NMP has been reported, which involved
refluxing the mixture of graphite fluoride and NMP, followed by sonication at room temperature [70–74]. Similar to the exfoliation in ionic liquid, surface energy matching and
intercalation of NMP into the graphite fluoride layers might contribute to the exfoliation.
Strong shear force caused by ball milling in the presence of NMP also resulted in the exfoliation of graphene fluoride, which gave a high yield of 38% compared to other liquid-phase
methods [75]. The exfoliated sheets were assembled into a flexible film showing ultrahigh
thermal conductivity and good electrical insulation. Exfoliation of graphene fluoride has
also been achieved with DMF using sonication or microwave-assisted methods [76,77].
A one-pot sonochemical preparation of graphene fluoride in chloroform was reported
by Zhu et al. [78]. The exfoliated nanosheets had a lateral size of 200–500 nm and an
average thickness of 0.8 nm. The use of chloroform and acetonitrile as liquid media for
the exfoliation was also studied by Sun et al. [79]. Wrinkled few-layer graphene fluoride
sheets with disordered edges and poor stacking order were observed. It was found that
the intercalation of chloroform resulted in partial transformation of C–F bonds from covalent to semi-ionic bonds. Wang et al. prepared graphene fluoride by adding graphite
fluoride, dopamine, and cetyl-trimethyl-ammonium bromide (CTAB) into Tris-HCl solution. The mixture was subjected to sonication to produce the exfoliated sheets [80]. The
exfoliation of fluorinated graphene oxide can also be performed in deionized water with
sonication [81]. The presence of hydrophilic oxygen-containing groups on the surface of
fluorinated graphene oxide facilitated its dispersion in water.
Table 1 shows a summary of the conditions used in those reports, including the
boiling points and surface tensions of the solvents, relative polarity, exfoliation methods
and temperatures, and post-processing. Note that there are roughly two groups of liquid
media used depending on their boiling points and surface tensions: solvents with relatively
lower boiling points (61–82 ◦ C) and surface tensions (22–30 mN/m) such as ethanol, IPA,
chloroform, and acetonitrile; and solvents with higher boiling points (153–285 ◦ C) and
surface tensions (37–46 mN/m) such as sulfolane, NMP, and DMF. The latter typically
involves additional post-processing steps, e.g., washing with water/ethanol and/or freezedrying to remove the solvents. The use of water as the liquid exfoliation medium could be
more attractive for sustainable applications. In addition, polar solvents are typically used
for the intercalation and exfoliation. Note that some of the polar aprotic solvents such as
NMP and DMF have been found to induce partial defluorination due to the interaction
between graphene fluoride and the solvent molecules [72,77,79].
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Table 1. A summary of the conditions used in liquid-phase exfoliation strategies.
Solvent
Boiling
Point (◦ C)
Surface
Tension at
20 ◦ C (mN/m)
Relative
Polarity
Exfoliation
Method
Exfoliation
Temperature
(◦ C)
Post-Processing
Ref
Sulfolane
285
46.0 (50 ◦ C)
0.41
Sonication
(B)
50
Separate supernatant
[64]
IPA
82.5
23.0
0.55
Sonication
-
-
[26]
IPA
82.5
23.0
0.55
Sonication
-
Centrifuge; Freeze
drying
[65]
IPA
82.5
23.0
0.55
Sonication
(B)
-
Centrifuge
[66]
Ethanol
78.4
22.1
0.65
Sonication
-
-
[67]
Ethanol
78.4
22.1
0.65
Sonication
(B)
-
Remove sediment
using separatory
funnel
[68]
[bmim]Br
-
-
-
Sonication
(B)
-
Centrifuge; Wash
with ethanol
[69]
NMP
202
40.8
0.36
Sonication
(B)
RT
-
[70]
NMP
202
40.8
0.36
Sonication
(B)
RT
Wash with water;
Freeze drying
[71]
NMP
202
40.8
0.36
Sonication
(B)
RT
Filtration; Freeze
drying
[72]
NMP
202
40.8
0.36
Sonication
(B)
RT
Filtration; Freeze
drying
[73]
NMP
202
40.8
0.36
Sonication
(B)
-
Centrifuge; Washing;
Freeze drying
[74]
NMP
202
40.8
0.36
Sonication
(B)
RT
-
[111]
NMP
202
40.8
0.36
Ball milling
RT
Centrifuge; Washing;
Freeze drying
[75]
DMF
153
37.1
0.39
Sonication
-
Separate supernatant
[76]
DMF
153
37.1
0.39
Sonication
-
Centrifuge
[77]
Chloroform
61.2
29.9 (0 ◦ C)
0.26
Sonication
(P)
0
Centrifuge
[78]
Chloroform
Acetonitrile
61.2
82
27.5
28.9
0.26
0.46
Sonication
RT
Re-disperse in NMP;
Centrifuge; Filtration
[79]
Water
(surfactant)
100
-
1.00
Sonication
RT
Filtration; Wash with
water; Freeze drying
[80]
Water
100
72.8
1.00
Sonication
-
-
[81]
Sonication (B), bath sonication; Sonication (P), probe sonication; RT, room temperature.
4.4. Electrochemical Exfoliation
The simultaneous fluorination and exfoliation of graphite may be achieved by electrochemical method in electrolytes containing HF as fluorinating agent (10 w.%) [82]. Fluorine
content, defect density morphology and structure of the prepared powders, mainly multilayered graphene sheets, can be tailored according to the applied voltages. It is to be noted
that HF solution is not a proper electrolyte for the preparation of few-layered graphene
sheets. Moreover, the addition of TiO2 (2.5 g/L) in the HF solution had positive effects on
both exfoliation and fluorination of graphene sheets. TiO2 particles can be dissolved in HF
solutions, forming TiF6 − ions, which may favor the exfoliation.
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5. F-Diamane
Atomically thin diamond, namely “diamane”, has recently emerged as a new twodimensional carbon allotrope. Unlike graphite which has a layered structure, diamond
possesses a three-dimensional crystalline structure that becomes unstable when thinned
down to the thickness comparable to the dimensions of diamond’s unit cell. Chemical
modifications of the surface carbons with specific functional groups using fluorination
(F-diamane) or hydrogenation (H-diamane) are necessary to stabilize the structures at ambient conditions. Recently, theoretical studies predicted the conversion of graphene layers
into ultrathin diamond films by attaching fluorine atoms (or hydrogen atoms or hydroxyl
groups) to the surface of graphene [65,83–85]. For example, complete fluorination of a
monolayer graphene can yield a thermodynamically stable sp3 -bonded layer [86]. The evidence of fluorination of monolayer graphene membranes has been shown experimentally.
Later, Odkhuu et al. [87] showed that when a one-side surface of a supported graphene
bilayer grown/coated on a transition metal surface is fluorinated, the energetics for the
conversion to sp3 -bonded films were significantly lower than that for the free-standing
bilayer [87].
Recent advances in the growth of large-area, high-quality graphene films with a
precisely controlled number of layers have suggested promising pathways for experimental conversion of graphene into “diamane” films. Bakharev et al. [88] reported that
chemisorption of fluorine on chemical vapor deposition grown bilayer graphene resulted
in the formation of an F-diamane film [88]. In their experiment, bilayer graphene films
grown on CuNi (111) surface were fluorinated at 65 ◦ C under 50–60 Torr vapor pressure
of XeF2 . It was found that, by changing the fluorination conditions (temperature, XeF2
partial pressure, and exposure time), the fluorinated graphene structures can be controlled
to have different C/F ratios. The F-diamane film was found to be an ultra-thin wide-band
gap semiconductor. Rajasekaran et al. reported experimental evidence that hydrogen adsorption could induce partial phase transition of few layers of graphene to a diamond-like
structure on Pt(111) [89]. Hot filament process has been used to expose bilayer graphene to
hydrogen radicals for the preparation of diamane films [90–92]. UV Raman spectroscopy
was used in their studies to track the structure conversion, which showed the presence
of a sharp sp3 -bonded carbon stretching mode and absence of sp2 -bonded carbon peak.
Based on the experimental studies of diamane, density functional theory (DFT) simulations
have also been used to explore the stability, mechanical, electronic, and optical properties
of diamane nanosheets [93]. Zheng et al. [94] studied the vibrational properties of diamane nanoribbons [94]. Compared with graphene, diamane resonator showed a higher
natural frequency and a larger quality factor on the order of 105, and it could be useful for
developing ultra-sensitive resonator-based nanosensors.
6. Chemical Bonding and Related Properties
The C–F bonding in FG has been extensively discussed in the in-depth review from
Feng et al. [34]. As in graphite fluorides, the C–F bonding is highly versatile in FG and
strongly depends on both the fluorine content (F/C atomic ratio) and the distribution of
F atoms along the graphene layer(s). The C–F bonds in FG are mainly covalent but their
weakening may occur when non-fluorinated sp2 carbon atoms are located around the C–F
bonds. Hyperconjugation between C–F and sp2 C occurs [95,96]. The terms of weakened
covalence appear more significant than semi-covalent (semi-ionic). The C–F bond length is
close to 0.17 nm, as in room temperature graphite fluoride, whereas a C–F bond in fully
fluorinated neighbor is 0.14 nm long [24]. A recent study using polarized attenuated total
reflectance - Fourier transform infrared spectroscopy (ATR-FTIR) evidenced two types
of C–F bonds (Figure 4): the first are linked at the coplanar carbon atoms in the weakly
fluorinated region (Cx F, x ≥ 2), whereas the second type are in cluster at the strongly
deformed carbon framework with an F/C ratio of about 1 [97]. The coplanar structure of
weakly fluorinated graphene sheets (weakened covalence) is more likely to transform to
the planar aromatic ring with the breaking of the C−F bond more easily as compared with
ionic C−F bonds ha
excellent rate capability compared to covalent C−F bonds. The C−F b
parison, the covalent C−F bonds exhibit higher stability and higher bond dissociation enC 2021, 7, 20
tends to transform to the planar aromatic ring with the breaking of the C−F bond as com-
10 of 23
and heterolytic cleavage of the C−F bond were rathe strong fluorinated nonplanar region (covalent). In comparison with C−F bonds with
weakened covalence, semi-ionic C−F bonds have a higher discharge voltage and a more
excellent rate capability compared to covalent C−F bonds. The C−F bond with weakened
We strongly covalence
agree with can
the authors
of this work
wholeading
claimedtothat
appearsofasconductivity
a “viable
be selectively
reduced,
theFG
recovery
[98]. By
comparison, the covalent C−F bonds exhibit higher stability and higher bond dissociation
energy,
which is equal to 460 kJ/mol. The coplanar structure of the weakly fluorinated
counterpart of
Teflon”.
region tends to transform to the planar aromatic ring with the breaking of the C−F bond
as compared with the strong fluorinated nonplanar region [97].
Figure 4. Changes of the F/C ratio and color during the fluorination of rGO with F2 /N2 mixture (a); scheme of polarized
ATR-FTIR acquisition (b) and data (c) related to C–F bonding (reproduced/adapted with
– permission from ref [97], Copyright,
2016, American Chemical Society).
The energies required
for homo- and heterolytic cleavage of the C−F bond were rather
–
high (418 kJ/mol). As an additional proof of the hyperconjugation, the energy required
for homolytic cleavage decreased significantly as the fluorine content decreased in FG [99].
This may result in spontaneous loss of fluorine atoms from FG with low F content. We
agree
with the authors of this work who claimed that FG appears as a “viable
tution of C−Fstrongly
bonds by
C−NH
precursor
for
the
synthesisThe
of graphene
derivatives
and cannot
bebond
regarded
ring of ethylenimine of these groups.
dissociation
and migration
of C−F
facili-as a chemical
counterpart
of Teflon”.
tates the dissociating
of C−C
bonds and the recombining of C−N bonds.
The difference in stability affects the electrochemical performances in energy storage
devices, as discussed thereafter.
The decrease in stability of C–F bonds with weakened covalent may favor other
functionalization of graphene. Defluorination assists the N-doping of graphene with a
large doping degree [100]. In comparison with GO, FG possesses a higher reactivity with
ammonia, enabling nitrogen doping to proceed efficiently at a lower temperature via
substitution of C−F bonds by C−NH2 groups followed by the cyclization to the threemembered ring of ethylenimine of these groups. The dissociation and migration of C−F
bond facilitates the dissociating of C−C bonds and the recombining of C−N bonds.
The C–F bonding may be estimated by the stability under electron beam irradiation.
The double-sided fluorinated graphene exhibited a much stronger stability than the singlesided fluorinated graphene under the same irradiation dose [29]. According to DFT
calculations, the configuration of double-sided fluorinated graphene has a negative and
C 2021, 7, 20
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low formation energy and then an energetically stable structure contrary to single-sided
fluorinated graphene.
7. Applications
7.1. Tribological Performances
In today’s world, so much energy is lost due to friction in mechanical components. To
address this issue, lubricant is added because it not only removes the friction heat but also
reduces unnecessary energy loss by reducing the wear and friction [101,102]. In order to
enhance the performance of the lubricant, adding lubricant additives is an indispensable
strategy. The lubricant additive owns many different functionalities, such as anti-wear,
anti-oxidation, anticorrosion, defoaming capability, viscosity modifier, dispersant, etc.
[103–105].
In recent years, 2-dimensional (2D) layered materials including tungsten disulfide
(WS2 ), molybdenum disulfide (MoS2 ), graphitic materials, and hexagonal boron nitride
(h-BN) have been widely used as solid lubricants owing to their easy shear between lattice
layers [106–108]. These 2D materials have been extensively investigated for a better adaptability to extreme environmental conditions and contact pressures [106]. In addition, there
have been consistent efforts by the researchers worldwide to improve their tribological
performance, i.e., anti-wear and friction reduction performance [108]. Among various
2D materials, graphene has attracted worldwide attention because it exhibits excellent
electrical, thermal, mechanical, stable chemical properties [109], as well as tribological
properties [110]. Thanks to these unique properties, graphene-based materials are widely
used as lubricant additives. In fact, graphene film can significantly decrease the friction coefficient between friction pairs [111,112]. Furthermore, the small-sized nanosheets
with only a few nanometer thickness allow graphene to easily enter the friction contact
surfaces [113,114]. Despite its interesting properties, pristine graphene has some disadvantages including structural defects and chemical inertness which is induced by the
delocalized π electron system [115]. The strong π−π interaction between graphene layers
restricts the interlayer slippage of graphene [111]. The chemical inertness of graphene
hinders the stable formation of a solid tribofilm on the friction pairs [116], limiting the
lubrication and wear-resistance performances of graphene at the macroscale. Moreover,
the friction coefficient of graphene is not sufficiently low at the macroscale. To overcome
these shortcomings, the design of novel graphene-based materials has become a critical
component of emerging technologies. Therefore, researchers have focused on functionalizing pristine graphene to form free radicals or functional groups which could improve
the overall properties of the material, i.e., surface activity, structural integrity, and processability without altering the unique carbon conjugated structures of graphene [111,117].
In the literature, several types of functionalization methods have been reported and the
modified graphene nanosheets showed an excellent performance of friction reduction and
anti-wear as lubricant additives. Covalent functionalization has been commonly used
to obtain functionalized graphene, including graphene oxide (GO) [118], polydopaminefunctionalized GO [119], hydrogenated graphene [120], and acid-grafted graphene [121].
Furthermore, the functionalized graphene exhibited worse chemical and thermal stabilities
compared to graphene, owing to the large contents of surface substituents or defects [34].
The functionalized graphene structures such as GO and hydrogenated graphene exhibited
higher frictions attributed to their higher surface energies [122,123]. In addition, the tribological performances of graphene-related materials are largely restricted by the external
environment [124–126]. Fluorographene is another important class of graphene-derived
material, and has attracted an immense research interest since its introduction in 2010 [32]
due to its excellent performances [32,42,46,64,67,115,127–133]. FGs not only hold the properties of graphene but also possess the characteristics of fluorine-based materials such as
excellent thermal and chemical stability, mechanical strength, and larger interlayer distance
compared to pristine graphene [134]. FG inherits the excellent mechanical properties of
graphene even though fluorination disrupts the van der Waals forces between the FG
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sheets [135]. Thus, FG is widely used as lubricant additive thanks to its outstanding tribological performance [32,136,137]. For instance, Ye et al. [138] reported that FG can be
used to enhance the mechanical properties of polymers; also Liu et al. [111] evidenced that
FG coating on a stainless-steel substrate exhibited an excellent lubrication performance,
which reduced the friction by a factor of 2. Kwon et al. [47] investigated the effect of
fluorination on friction, adhesion, and the charge transport properties of chemical vapor
deposition (CVD)-grown graphene using ultrahigh vacuum friction force microscopy and
their 2D characteristic spring model; the friction measured on FG was modulated up to
6 times larger than on pristine graphene, while fluorination slightly reduced the adhesion
force [47]. In addition, Hou et al. [73] prepared FG by liquid-phase exfoliation of graphite
fluoride, and the friction tests confirmed that FG could greatly enhance the anti-wear
property compared with pure base oil. Furthermore, Liu et al. [111] fabricated a fluorinated
graphene (FG) coating on a stainless-steel substrate by a simple electrophoretic deposition
in ethanol. The FG coating exhibited excellent lubrication performances under different
contact pressures which reduced the friction coefficient by 54.0% and 66.2% compared
to those of pristine graphene and GO coatings, respectively. The authors attributed the
lubrication enhancement of FG coating to its extremely low surface energy and interlaminar
shear strength [111]. However, although FG possesses numerous excellent properties, it
cannot be really applied in aqueous environments due to its high hydrophobicity [59].
To address this issue, Ye et al. [72] have reported the covalent functionalization of FG by
urea via part replacement of fluorine (UFG), and such replacement can change the surface
wettability of FG from hydrophobicity to hydrophilicity. The authors have evidenced
that the prepared UFG has a very good dispersibility in water, which allows UFG, as an
effective lubricant additive, to enhance the tribological property of the water. Tribological
tests have demonstrated that the sample of UFG-1 exhibited the best antiwear ability
with a 64.4% decrease of wear rate compared with that of the pure water (UFG-0) [72].
Li et al. [139] combined experiments and molecular dynamics simulations to propose a
novel mechanism in which friction can be altered over a wide range by fluorination; the
friction force between silicon atomic force microscopy tips and monolayer fluorinated
graphene can range from 5−9 times higher than for graphene. The proposed mechanism
suggests that the dramatic friction enhancement results from increased corrugation of the
interfacial potential due to the strong local charge concentrated at fluorine sites, consistent
with the Prandtl–Tomlinson model. The monotonic increase of friction with fluorination
in experiments also demonstrates that friction force measurements provide a sensitive
local probe of the degree of fluorination [139]. Recently, an interesting contribution by
Fan et al. [140] reported the development of a novel and simple means to achieve lossless
covalent functionalization of FG by activating dormant radicals, improving its water dispersibility, and simultaneously maintaining intrinsic self-lubricating ability with limited
commensurate stacking and weak interlayer interactions. The obtained materials present
excellent tribological performances as a water-based lubricant additive and are regarded as
an ecofriendly and sustainable system, whose friction coefficient and wear rate have about
66% and 82% decrease compared to that of polyethylenimine (PEI) grafted fluorinated
graphene (FG-PEI), respectively [140].
A low fluorine content CF0.05 in FG resulting from thermal exfoliation using a thermal
shock is enough to achieve low friction coefficient remarkably as soon as the first friction
cycle (Figure 5) [141]. Although there is massive defluorination during exfoliation, the
comparison of raw and exfoliated graphite fluorides evidenced that exfoliation does not
deteriorate the excellent lubricating performances because of the weakening of the interparticles’ interactions due to the exfoliation process. Exfoliated structure may facilitate the
formation of a homogeneous and stable tribofilm even if the fluorine content is low.
–
C 2021, 7, 20
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Figure 5. Friction coefficients after 10 cycles (a) and as a function of cycle number (b) of raw graphite fluoride (F-Gr) and
thermally exfoliated graphite fluoride (Exf-FG), evaluated under air atmosphere using a ball-on-plane tribometer in which
a ball describes a reciprocating motion on a static steel plane (c) (reproduced/adapted with permission from ref [141],
Copyright, 2016, Royal Society of Chemistry).
According to the fluorination route, the friction properties differ. Compared with FG
synthesized using exfoliation method, FG prepared by direct gas fluorination has uniform
size distribution and similar thickness. Furthermore, F/C ratios of FG synthesized by gas
fluorination could be controlled easily by regulating the heating temperature. FG with
higher F/C ratio significantly enhanced the friction reduction and anti-wear properties as
–
lubricant additive
because more covalent C–F bonds are present that could ensure steady
chemical properties during the friction process [116]. On the other hand, the size of FG was
reduced with the increase of F/C ratio because of the special properties of synthesizing
method. The small size made it possible for FG to enter the contact area easily, thus
improving the good tribological properties of FG.
7.2. Energy Storage
Modified graphenes have been successfully considered for energy and storage applications over the years [142–144]. In particular, fluorinated graphene is one of the most
promising materials for energy application thanks to its tunable electrochemical properties,
its lightweight, high in-plane conductivity and mechanical strength which make FG a
promising material for energy applications. FG used as cathode material for primary
lithium battery could open the way for high-performance Li primary cells for large-scale
applications. FG obtained through chemical exfoliation of graphite fluoride (CF0.25 )n exhibited enhancements in both energy density and power capability along with exceptional
faradaic yield, all achieved in a single step [145]. As claimed by the authors, the obtained
specific capacity for FG derived from (CF0.25 )n was comparable to the theoretical capacity
of (CF0.75 )n . Further improvements in electrochemical performances could be achieved
C 2021, 7, 20
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by optimizing the fluorine content in the starting material. Meduri et al. [130] studied
the effect of fluorine content in fluorinated graphene on the structure and electrochemical
properties when these materials were used as cathode materials in primary lithium battery.
FG used was synthesized by partial fluorination of graphene having high and moderate
fluorine content, i.e., F/C = 0.47, 0.66, and 0.89; the material with the highest fluorine
content (CF0.89 ) consisted of stacked graphene layers with surface insulating groups such
as CF2 and CF3 which were considered as structural defects that hindered the electrochemical performance. In contrast, CF0.47 composed of fluorine primarily on the surface with
small amounts of CF2 and CF3 groups led to the lowest overall resistance [130]. Compared
to graphite fluoride, the transport of solvated Li+ ions within fluorinated graphene was
greatly improved, benefiting the high-rate performance. In addition, the large amounts
of residual graphene domains along with defective sites also contributed to the greatly
improved performance of CF0.47 . The distribution of the discharge product LiF clearly
indicated the original location of C–F bonding, and thus appears as a good electrochemical
approach to probing fluorine atoms on graphene (providing information for the indirect
detection of functional groups) [78].
Lim et al. [37] also showed the importance of the amount of fluorine if FG is considered
for energy and sensing applications. The electrochemical and electrocatalytic properties
of three FGs, namely, CF0.02 , CF1.02 , and CF1.39 were investigated in order to evidence the
impact of different fluorine levels. FGs exhibited enhanced electrochemical sensing in
various biomarkers, including uric acid, ascorbic acid, and dopamine, and also in energy
applications, such as hydrogen evolution and oxygen reduction over the bare glassy carbon
electrode surface [37]. The higher the fluorine level, the higher the electrochemical and
electrocatalytical performance [71].
FG use is of concern not only as cathode materials in primary Li batteries but also as
anodic material in lithium ions batteries. Cheng et al. [146] reported a fluorinated graphenemodified Li negative electrode (LFG) for high-performance lithium−oxygen (Li−O2 ) cells;
only 3 w.% FG introduction leads to a significant enhancement on rate capability and
cycling life of Li electrodes. Compared with the half cells with bare Li, the cells with LFG
exhibit much more stable voltage profiles even at a large areal capacity up to 5 mAh cm−2
or a large current density up to 5 mA cm−2 [146]. Two significant improvements were
achieved: (i) Li−O2 cells with the LFG anode show a longer cycle life than the cell with the
pristine lithium anode, (ii) a LiF-rich layer could be in situ built upon cycling when FG is
used, which ensures uniform Li stripping/ plating and effectively suppresses Li dendrite
growth [146]. In fact, lithium dendrite growth is harmful for the battery performances as
the incessant lithium dendrite growth during charge/discharge cycles of the battery will
pierce the separator, and the Li dendrite will finally reach the cathode, leading to cell short
circuit [147]. It also induces cracking and collapsing of the solid electrolyte interphase (SEI)
layer, rendering a more exposed fresh Li surface and more parasitic reactions with the
electrolyte, causing low coulombic efficiency and short cell life [148,149].
In spite of the relatively high fluorine content achieved during hydrothermal process [56], high electrical conductivity may be maintained thanks to the predominance of
C–F bonds with weakened covalence. High pseudo-capacitance and improved specific
capacitance (227 F/g), power density as high as 50 kW/kg (at the current density of 50 A/g)
as well as good rate capability were achieved in supercapacitor. The hydrothermal temperature of 150 ◦ C appeared to be the best to reach those performances. Maintaining the C–F
bonds with weakened covalence appears as a key point to achieve good performances in
supercapacitors. The fluorination time is a parameter to both favor those bonds and limit
the formation of groups (such as CF2 , CF3 , etc.) in fluorine-rich surface; those ones are
electrochemically inactive. This was clearly evidenced for FG obtained with hydrothermal
fluorination of a GO suspension and used as electrode materials for supercapacitors [150].
An impressive specific capacitance of 1222 F/g at 1 A/g has been reported when a fluorinated graphene (GF) obtained at the optimal fluorination was included in composite with
CoAl-layered double hydroxide (LDH) with a thermal process too. LDH crystals were in
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situ anchored on the surface of FG. The electronic conductivity and transport performance
of C−F bonds with weakened covalence allow the high performances to be reached.
In spite of their high specific surface area, a low capacitance of thermally exfoliated
graphite fluorides was recorded in supercapacitor with an aqueous electrolyte (about
21 F/g), which was related with the hydrophobic behavior [63]. With such an aqueous
electrolyte, the presence of C–F bonds is detrimental and the surface chemistry must be
changed in order to improve the wettability of the electrode by adding redox active oxygen
species as the authors of this work did; the specific capacitance increased to 158 F/g after a
mild oxidation in a mixture of concentrated H2 SO4 /HNO3 .
7.3. Gas Sorption and Sensing
Molecular simulations have been used to reveal the effect of fluorination of graphene
surfaces on the adsorption of various gases. Studies suggested that fluorine-modified
porous graphene membrane might provide excellent selectivity for the separation of
CO2 /N2 [151]. DFT calculations and experimental studies revealed that the C–F bonds in
graphene fluoride improved adsorption of NH3 molecules and provided a higher sensitivity compared to pristine graphene [59]. Fluorinated graphene also showed sensitivity
to ethanol, methane, and formaldehyde gases [152]. The introduction of fluorine into
graphene-based materials can improve gas-sensing properties given that the fluorine
could modify the surface chemistry and electrical properties of the materials. Fluorinated
graphene oxide-based sensors have been reported for sensing NH3 , showing improved
sensitivity, selectivity, and reversibility with a significantly low theoretical detection limit
of ~6 ppb at room temperature [153–155]. DFT calculations revealed the role of fluorine in
changing the charge distribution on the functional groups in graphene oxide, leading to
selective adsorption and desorption of NH3 molecules. In addition, the effects of chemical
modifications of graphene fluoride with hydrazine [155] or hydroxyl species [156] on the
adsorption of gas molecules have been revealed. The fluorinated graphene sensor showed
a much better regeneration after simply purging with Ar at room temperature. DFT calculations indicated that NH3 and NO2 molecules are adsorbed on fluorine, hydroxyl groups,
and the carbon atoms close to the functional groups. Oxyfluorinated graphene is expected
to have a stronger adsorption energy for NH3 due to the short N/H(O) contact.
Graphene fluoride has been used for electrochemical sensing of ascorbic acid and uric
acid. It was found that increasing the level of fluorination up to CF0.75 led to improved
performance on both the response linearity of the electrode and resolution of the oxidation
peaks of the sensing molecules [37,157]. Graphene fluoride has also been used in a biosensor
platform for electrochemical detection of NADH and dopamine [43]. Fluorinated graphene
functionalized with thiol groups showed an effective DNA impedimetric sensitivity. This is
attributed to the interactions between the DNA strands and thiol groups. DFT calculations
showed that the thiol-modified graphene derivatives were thermodynamically stable
only when fluorine adatoms were present on the graphene [158]. The use of fluorinated
graphene oxide as a sensing material for the simultaneous detection of various heavy metal
ions has been reported [159]. Recently, fluorinated graphene oxide sensor was also used
for detecting caffeic acid in wine [160].
Taking benefit of hydrogen bonding between FG and water molecules, a resistive
humidity sensor with FG as sensitive material was developed. According to DFT calculations, the hydrogen atoms of the water molecule move towards the fluorine atom of the FG
during the relaxation process [161].
7.4. Nanocomposites and Coating
Presence of fluorine atoms allows the surface energy to be adjusted at a value closer
than the one of hydrophobic polymer matrix (e.g., polypropylene) for the preparation
of composites. Thanks to the improved exfoliation and dispersion of the filler in the
polypropylene (PP) matrix, the composites with FG showed little improvement in mechanical properties and a sharp drop in elongation at break [57]. With the same strategy
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of filler/matrix tailoring of their surface energy, fluorinated graphene/polyimide (PI)
nanocomposite films were prepared. Because of their individual graphitized planar structure, their high surface area, and the presence of some oxygen-containing functional groups,
excellent dispersion of the FG nanosheets in the PI matrix has been achieved. The hydrophobicity, which is provided by F atoms, associated with low dielectric constant, low
dissipation factor, and good optical properties makes these films promising for advanced
electronic packaging of fan-out wafer level package (FO-WLP).
Highly thermally conductive and electrically insulating materials for heat dissipation
are required for portable and flexible electronic devices. FG-based composite films with
well-organized alignment of fluorocarbon layers along the in-plane direction exhibit the
needed characteristics, i.e., ultrahigh in-plane thermal conductivity (61.3 W m−1 K−1 ) and
mechanical flexibility [66]. Polyvinyl alcohol was added to FG (from graphite fluoride
sonically exfoliated) in order to both facilitate the uniform dispersion of FG in water and
enhance the linking between adjacent FG nanosheets.
FG coating on Cu plain surface is able to enhance the boiling heat transfer performance [48]. The heat transfer performance was enhanced thanks to the hydrophobicity of
C–F bonds’ surface against the nonpolar molecule of refrigerant that created more boiling
active sites and increased the bubble size. In other words, the vaporization is catalyzed on
the fluid/graphene interface. The chemical stability of FG during harsh thermal cycling
operation is higher than conventional polymer coating.
8. Conclusions
The aim of the present review was to exhaustively present the synthesis routes of
fluorinated graphenes. The fluorinating agent for fluorination or exfoliation must be
chosen according to the precursor and its quality (number of layers, i.e. monolayer,
few-layers, presence of defects, functional groups with oxygen). The direct fluorination
of graphene oxide with molecular fluorine appears to be the easier route to produce
fluorinated graphene at large-scale but the resulting materials contain residual oxygenated
groups. The quality of the resulting FG depends on the quality of the precursor; methods
other than direct fluorination with F2 , such as fluorinating agent (XeF2 ) must be used
and the cost is significantly increased. Thermal and liquid phase exfoliations appear
to be intermediate in terms of cost and quality. The thermal exfoliation results in low
fluorine content because of simultaneous exfoliation/defluorination. On the contrary,
exfoliation in the liquid phase allows high fluorine content to be maintained but the use
and removal of organic solvents complicate the method and acts in the final yield. The
main applications are also discussed, for energy storage, lubrication, gas sorption and
sensing, and nanocomposites.
Whatever the use, careful attention must be paid to the C–F bonding in addition to the
fluorine content. Figure 6 summarizes the main application as a function of the F/C ratio.
Most of those applications may be planed only if cytotoxicity of fluorinated graphene is
fixed. The cytocompatibility of fluorinated graphene has been studied by comparing the
biological responses of cells to graphene treated by SF6 plasma at different F contents [53].
Thanks to the presence of C–F bonds, biological response to rat bone mesenchymal stem
cells (rBMSCs) and cytotoxity are good as well as the facilitation to cell adhesion at early
stage. However, for the case of fully fluorinated graphene, the cell viability decreased. In a
general way, the biological response depends on the fluorine content, i.e., on both the C–F
bonding and the maintaining of sp2 carbon providing possible π–π interaction between the
surface of FG and biologic component. The adhesion and aggregation of blood platelets
is reduced. Favorable antibacterial ability against E. coli of partially fluorinated graphene
was also evidenced in this work.
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Figure 6. Some applications of fluorinated graphenes, in supercapacitors ((a) reproduced with
permission from [162], Copyright, 2014, American Chemical Society), conductive films ((b) reproduced with permission from [66], Copyright, 2019, American Chemical Society), electronic devices
((c,d), reproduced with permission from [60], Copyright, 2011, American Chemical Society and [33]
Copyright, 2010, American Chemical Society), lubricants ((e) reproduced with permission from [47],
Copyright, 2012, American Chemical Society), lithium ions battery ((f) reproduced with permission
from [163], Copyright, 2016, Wiley) and gas sensors (here NH3 ) ((g) reproduced with permission
from [59], Copyright, 2016, American Chemical Society).
Author Contributions: All authors have contributed substantially to the present review. All authors
have read and agreed to the published version of the manuscript.
Funding: This research was funded by I-Site CAP2025, Université Clermont Auvergne, and Clermont
Auvergne Métropole for support via the Académie CAP20-25.
Institutional Review Board Statement: Not applicable.
Informed Consent Statement: Not applicable.
Acknowledgments: Marc Dubois acknowledges I-Site CAP2025, Université Clermont Auvergne,
and Clermont Auvergne Métropole for support via the Académie CAP20-25.
Conflicts of Interest: The authors declare no conflict of interest.
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