IPHAS and the symbiotic stars
Quentin A Parker2008, Astronomy and Astrophysics
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Context. The study of symbiotic stars is essential to understand important aspects of stellar evolution in interacting binaries. Their observed population in the Galaxy is however poorly known, and is one to three orders of magnitudes smaller than the predicted population size. Aims. IPHAS, the INT Photometric Hα survey of the Northern Galactic plane, gives us the opportunity to make a systematic, complete search for symbiotic stars in a magnitude-limited volume, and discover a significant number of new systems. Methods. A method of selecting candidate symbiotic stars by combining IPHAS and near-IR (2MASS) colours is presented. It allows us to distinguish symbiotic binaries from normal stars and most of the other types of Hα emission line stars in the Galaxy. The only exception are T Tauri stars, which can however be recognized because of their concentration in star forming regions. Results. Using these selection criteria, we discuss the classification of a list of 4338 IPHAS stars with Hα in emission. 1500 to 2000 of them are likely to be Be stars. Among the remaining objects, 1183 fulfill our photometric constraints to be considered candidate symbiotic stars. The spectroscopic confirmation of three of these objects, which are the first new symbiotic stars discovered by IPHAS, proves the potential of the survey and selection method.
Related papers
IPHAS and the symbiotic stars . II. New discoveries and a sample of the most common mimics
Astronomy & Astrophysics, 2010
Context. Knowledge of the total population of symbiotic stars in the Galaxy is important for understanding basic aspects of stellar evolution in interacting binaries and the relevance of this class of objects in the formation of supernovae of type Ia. Aims. In a previous paper, we presented the selection criteria needed to search for symbiotic stars in IPHAS, the INT Hα survey of the Northern Galactic plane. IPHAS gives us the opportunity to make a systematic, complete search for symbiotic stars in a magnitudelimited volume. Methods. Follow-up spectroscopy at different telescopes worldwide of a sample of sixty two symbiotic star candidates is presented. Results. Seven out of nineteen S-type candidates observed spectroscopically are confirmed to be genuine symbiotic stars. The spectral type of their red giant components, as well as reddening and distance, were computed by modelling the spectra. Only one new Dtype symbiotic system, out of forty-three candidates observed, was found. This was as expected (see discussion in our paper on the selection criteria). The object shows evidence for a high density outflow expanding at a speed ≥65 km s −1 . Most of the other candidates are lightly reddened classical T Tauri stars and more highly reddened young stellar objects that may be either more massive young stars of HAeBe type or classical Be stars. In addition, a few notable objects have been found, such as three new Wolf-Rayet stars and two relatively high-luminosity evolved massive stars. We also found a helium-rich source, possibly a dense ejecta hiding a WR star, which is surrounded by a large ionized nebula. Conclusions. These spectroscopic data allow us to refine the selection criteria for symbiotic stars in the IPHAS survey and, more generally, to better understand the behaviour of different Hα emitters in the IPHAS and 2MASS colour-colour diagrams.
The ongoing outburst of the new symbiotic star IPHASJ190832.31+051226.6
Astronomy and Astrophysics, 2010
Aims. Eleven new symbiotic stars have recently been discovered with IPHAS, the INT Hα survey of the Northern Galactic plane. The star IPHAS J190832.31+051226.6 was proposed as an additional candidate on the basis of the existing spectrum. Here, we investigate the nature of this source by means of additional observations. Methods. Photometric data, optical spectra obtained in 2006 and 2009, a higher resolution spectrum resolving the Hα profile, and near-IR spectra of IPHAS J190832.31+051226.6 are all presented. Results. The source brightened in the r band by 2.3 mag from 2004 to 2009. From 2006 to 2009, the spectrum has evolved from one with the obvious continuum of an M giant star plus HI and HeI lines in emission to a lower excitation nebular spectrum with HI, CaII, and FeII emission and a bluer continuum in which the absorption bands of the red giant are only visible at wavelengths longer than 7500 Å. The Hα line is broad with a deep central absorption and extended wings.
Discovery in IC10 of the farthest known symbiotic star ★
Monthly Notices of the Royal Astronomical Society: Letters, 2008
We report the discovery of the first known symbiotic star in IC10, a starburst galaxy belonging to the Local Group, at a distance of ∼750 kpc. The symbiotic star was identified during a survey of emission-line objects. It shines at V =24.62±0.04, V −R C =2.77±0.05 and R C −I C =2.39±0.02 and suffers from E B−V =0.85±0.05 reddening. The spectrum of the cool component well matches that of solar neighborhood M8III giants. The observed emission lines belong to Balmer series, [SII], [NII] and [OIII]. They suggest a low electronic density, negligible optical depth effects and 35,000<T eff <90,000 K for the ionizing source. The spectrum of the new symbiotic star in IC10 is an almost perfect copy of that of Hen 2-147, a well known Galactic symbiotic star and Mira.
NEW SYMBIOTIC STARS MONITORED WITH THE HERMES SPECTROGRAPH: A CASE STUDY OF ORBITAL H alpha MODULATION
We present new orbital elements for two symbiotic systems involving a giant of spectral type S, namely V420 Hya and ER Del. These orbital elements are compared with existing elements for S-type binaries and for symbiotic binaries with M-giant primaries. It is shown that among the S-type binaries, most of the short-period systems (with P in the range 300 -1000 d) exhibit some kind of symbiotic activity (Hα emission, UV continuum, hard X-rays), but symbiotic systems are not restricted to the short-period systems. The complex and varying Hα profile of V420 Hya has been decomposed to several components (broad emission with σ ∼ 140 km/s, narrow emission with σ ∼ 60 km/s, and narrow absorption components). Their orbital modulation reveals that the broad emission is located close to the companion (under the hypothesis of a system with a mass ratio M g /M c = 2), and that this broad emission is mutilated by absorption from matter located along the line of sight and flowing towards the observer (faster than the giant) at all orbital phases.
The new carbon symbiotic star IPHAS J205836.43+503307.2
Aims: We are performing a search for symbiotic stars using IPHAS, the INT Hα survey of the northern Galactic plane, and follow-up observations. Methods: Candidate symbiotic stars are selected on the basis of their IPHAS and near-IR colours, and spectroscopy and photometry are obtained to determine their nature. We present here observations of the symbiotic star candidate IPHAS J205836.43+503307.2. Results: The optical spectrum shows the combination of a number of emission lines, among which are the high-excitation species of [O iii], He ii, [Ca v], and [Fe vii], and a red continuum with the features of a star at the cool end of the carbon star sequence. The nebular component is spatially resolved: the analysis of the spatial profile of the [N ii]6583 line in the spectrum indicates a linear size of ~ 2.5 arcsec along the east-west direction. Its velocity structure suggests an aspherical morphology. The near-infrared excess of the source, which was especially strong in 1999, indicated that a thick circumstellar dust shell was also present in the system. The carbon star has brightened in the last decade by two to four magnitudes at red and near-infrared wavelengths. Photometric monitoring during a period of 60 days from November 2010 to January 2011 reveals a slow luminosity decrease of 0.2 mag. Conclusions: From the observed spectrophotometric properties and variability, we conclude that the source is a new Galactic symbiotic star of the D-type, of the rare kind that contains a carbon star, likely a carbon Mira. Only two other systems of this type are known in the Galaxy. Based on observations obtained with the 2.5 m INT and the 4.2 m WHT telescopes of the Isaac Newton Group of Telescopes and the 1.5 m Carlos Sanchez Telescope, operating on the islands of La Palma and Tenerife at the Spanish Observatories of the Roque de Los Muchachos and Teide of the Instituto de Astrofísica de Canarias; the 2.1 m telescope at San Pedro Martir, Mexico; and the GAPC 0.7 m Ritchey-Chrétien telescope at La Polse di Cougnes, Udine, Italy.
Light-curves of symbiotic stars in massive photometric surveys I: D-type systems
arXiv preprint arXiv: …, 2009
Abstract: ASAS, MACHO, OGLE and SAAO JHKL light curves of 13 stars, that have at some time been classified as D-type symbiotics, are analysed. Most of the near-IR light-curves that have been monitored over many years show long-term changes due to variable dust ...
High resolution spectroscopy of symbiotic stars
Astronomy and Astrophysics, 2001
We present new dynamical parameters of the AR Pav binary system. Our observations consist of a series of high resolution optical/NIR spectra from which we derive the radial velocity curve of the red giant as well as its rotation velocity. Assuming co-rotation, we determine the stellar radius (130 R) of the red giant. Based on this we derive the red giant's luminosity and mass (2.0 M) as well as the distance of the system (4.9 kpc). The binary mass function finally yields the companion's mass (0.75 M) and the binary separation (1.95 AU). We find that the red giant does not fill its Roche lobe. We review the radial velocity data of Thackeray & Hutchings (1974), and compare it with our red giant's orbit. We find that their RV curves of the blue absorption system and the permitted emission lines are in anti-phase with the red giant, and that the forbidden emission lines are shifted by a quarter of a period. The blue absorptions and the permitted emission lines are associated with the hot companion but not in a straightforward way. The blue absorption system only tracks the hot component's orbital motion whilst it is in front of the red giant, whereas at other phases line blanketing by interbinary material leads to perturbations. We finally present UV light curves based on IUE archive spectra. We clearly detect eclipses in the continuum at all wavelengths. The eclipse light curves are unusual in that they show a slow and gradual decline prior to eclipse which is followed by a sharp increase after eclipse.
High resolution spectral survey of symbiotic stars in the near-IR over the GAIA wavelength range
Arxiv preprint astro-ph/0208318, 2002
High resolution (R∼20,000), high signal-to-noise (S/N ≥ 100) spectra were collected for ∼40 symbiotic stars with the Asiago echelle spectrograph over the same 8480-8740Å wavelength range covered by the ESA Cornerstone mission GAIA, centered on the near-IR CaII triplet and the head of the Paschen series. A large number (∼ 140) of cool MKK giant and supergiant templates were observed with the same instrumentation to serve as a reference and classification grid. The spectra offer bright prospects in classifying and addressing the nature of the cool component of symbiotic stars (deriving T eff , logg, [Fe/H], [α/Fe], V rot sini both via MDM-like methods and syntetic atmosphere modeling) and mapping the physical condition and kinematics of the gas regions responsible for the emission lines.
Spectrophotometric study of southern symbiotic stars
Astronomy and Astrophysics
We have analyzed the optical spectra of 67 symbiotic stars and objects suspected of being symbiotic, and found 18 new symbiotic systems. This is the largest homogeneous set of optical spectrophotometric data for symbiotic binaries ever studied. We have derived the reddenings and distances for all systems, estimated the IR classes (S and D) for the new systems, and determined the location of the hot components in the Hertzsprung-Russell diagram.
Astronomy
&
Astrophysics
A&A 480, 409–419 (2008)
DOI: 10.1051/0004-6361:20078989
c ESO 2008
IPHAS and the symbiotic stars
I. Selection method and first discoveries⋆,⋆⋆
R. L. M. Corradi1,2 , E. R. Rodríguez–Flores2,3 , A. Mampaso2 , R. Greimel1 , K. Viironen2 ,
J. E. Drew4,5 , D. J. Lennon1,2 , J. Mikolajewska6 , L. Sabin2 , and J. L. Sokoloski7
1
2
3
4
5
6
7
Isaac Newton Group, PO Ap. de Correos 321, 38700 Sta. Cruz de la Palma, Spain
e-mail: [email protected]
Instituto de Astrofísica de Canarias, 38200 La Laguna, Tenerife, Spain
Instituto de Geofísica y Astronomía, Calle 212, N. 2906, CP 11600, La Habana, Cuba
Imperial College of Science, Technology and Medicine, Blackett Laboratory, Exhibition Road, London, SW7 2AZ, UK
Centre for Astrophysics Research, STRI, University of Hertfordshire, College Lane, Hatfield, AL10 9AB, UK
N. Copernicus Astronomical Center, Bartycka 18, 00-716 Warsaw, Poland
Columbia Astrophysics Laboratory, USA
Received 4 November 2007 / Accepted 10 December 2007
ABSTRACT
Context. The study of symbiotic stars is essential to understand important aspects of stellar evolution in interacting binaries. Their
observed population in the Galaxy is however poorly known, and is one to three orders of magnitudes smaller than the predicted
population size.
Aims. IPHAS, the INT Photometric Hα survey of the Northern Galactic plane, gives us the opportunity to make a systematic, complete
search for symbiotic stars in a magnitude-limited volume, and discover a significant number of new systems.
Methods. A method of selecting candidate symbiotic stars by combining IPHAS and near-IR (2MASS) colours is presented. It allows
us to distinguish symbiotic binaries from normal stars and most of the other types of Hα emission line stars in the Galaxy. The only
exception are T Tauri stars, which can however be recognized because of their concentration in star forming regions.
Results. Using these selection criteria, we discuss the classification of a list of 4338 IPHAS stars with Hα in emission. 1500 to 2000
of them are likely to be Be stars. Among the remaining objects, 1183 fulfill our photometric constraints to be considered candidate
symbiotic stars. The spectroscopic confirmation of three of these objects, which are the first new symbiotic stars discovered by IPHAS,
proves the potential of the survey and selection method.
Key words. surveys – Galaxy: stellar content – stars: binaries: symbiotic – stars: emission-line, Be – stars: pre-main sequence –
ISM: planetary nebulae: general
1. Introduction
Symbiotic stars are the interacting binaries with the longest orbital periods. They are composed of a compact star, in most
cases a hot white dwarf, accreting from the wind of a cool giant companion. Part of the giant’s wind is ionized by the white
dwarf, producing the composite spectrum containing both absorption features from a cool stellar photosphere and emission
lines from highly excited ions: these characteristics originally
caused these objects to be named “symbiotic”. Depending on
their near-IR colours, symbiotic stars are divided into “stellar”
(S) types, if colours are typical of red giant branch (RGB) stars,
⋆
Based on observations obtained at the 2.5 m INT telescope of the
Isaac Newton Group of Telescopes in the Spanish Observatorio del
Roque de Los Muchachos of the Instituto de Astrofísica de Canarias.
This publication makes use of data products from the Two Micron All
Sky Survey, which is a joint project of the University of Massachusetts
and the Infrared Processing and Analysis Center/California Institute
of Technology, funded by the National Aeronautics and Space
Administration and the National Science Foundation. This research has
also made use of the SIMBAD database, operated at CDS, Strasbourg,
France.
⋆⋆
Table 1 is only available in electronic form at
http://www.aanda.org
or “dusty” (D) types, if their near-IR emission shows a significant contribution from the warm dust known to be typical of
evolved asymptotic giant branch (AGB) stars. S-types account
for around 80% of the sample of known symbiotic stars. The
presence of an RGB or an AGB star also determines the orbital
separation at which the symbiotic phenomenon occurs; orbital
periods for the S-types are between 200 and 6000 days, while
they are longer for the D-types (>20 yr, but no single robust determination exists so far). For more details on the properties of
symbiotic stars, see e.g. Corradi et al. (2003).
A variety of phenomena occur in symbiotic stars that are
relevant to a number of important astrophysical problems. For
example, symbiotic stars have been proposed as potential supernova Ia progenitors (Munari & Renzini 1992; Hachisu et al.
1999). Also, symbiotic stars are excellent laboratories for studying (i) thermonuclear outbursts (nova-like accretion instabilities)
under a wide range of conditions (cf. Munari 1997); (ii) the powering mechanism of supersoft X-ray sources (cf. Jordan et al.
1996); (iii) the collimation of stellar winds and the formation of
jets (cf. Tomov 2003) and (iv) bipolar (planetary) nebulae (cf.
Corradi 2003).
A crucial figure in the discussion of some of these topics
is the total number of symbiotic stars in the Galaxy. This is
Article published by EDP Sciences
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R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I.
basically unknown. In fact, no systematic search for symbiotic
stars in the Milky Way has been done so far, and the present
sample of 173 known Galactic systems (Belczyński et al. 2000),
plus another 26 suspected ones, is mainly the result of occasional discoveries during the study of peculiar, variable or
erupting stars, or of sparse objective prism surveys. This figure
should be compared with the predicted total number of symbiotic stars in the Galaxy, which spans two orders of magnitude: 3 × 103 (Allen 1984), 3 × 104 (Kenyon et al. 1993), 3 × 105
(Munari & Renzini 1992), and 4 × 105 (Magrini et al. 2003).
IPHAS, the INT Photometric Hα survey of the Northern
Galactic plane (Drew et al. 2005), gives us the opportunity to
improve the determination of this basic number. The search for
symbiotic systems in IPHAS takes advantage of the generally
strong Hα emission that characterizes this class of objects. In
this paper, we define our criteria for the detection of symbiotic
stars using the data from the IPHAS project, complemented by
near-IR colours from the 2MASS survey. The effectiveness of
the method is illustrated by the spectroscopic confirmation of
three new symbiotic stars.
2. The data
2.1. IPHAS
IPHAS is an international collaboration, whose aim is to produce
a complete, fully photometric, and spatially detailed Hα map of
the part of the Galactic Plane between latitudes −5◦ and +5◦ that
is visible from the Northern hemisphere. The IPHAS observations are obtained using the Wide Field Camera (WFC) at the
prime focus of the 2.5 m Isaac Newton Telescope (INT) on La
Palma, Spain. The WFC consists of a mosaic of four 2k×4k EEV
CCDs, providing a field of view of 34 × 34 arcmin2 with a sampling of 0.′′ 33 per pixel. The IPHAS images are taken through
three filters: a narrow-band Hα (λc = 6568 Å; FWHM = 95 Å)
and two broad-band Sloan r and i filters, with matched 120,
30, and 10 s exposures, respectively. In this way, the magnitude
range 13 ≤ r ≤ 20 is covered for point sources (the fainter end at
10σ). Pipeline data reduction and data distribution are handled
by the Cambridge Astronomical Survey Unit. The presentation
of the survey and further details can be found in Drew et al.
(2005).
At the time of writing this article, more than 90% of the
∼1800 square degrees of the northern Galactic Plane to be covered by IPHAS has been observed. A first photometric catalogue, containing more than 200 million objects, is about to
be released (González-Solares et al. 2008). From it, a list of
4853 Hα emitting stars with r < 19.5 mag has been extracted
by Witham et al. (2008). This is the sample that we consider in
this paper for our first search for symbiotic stars within IPHAS.
Independently, we are employing other methods to select both
point-like and extended Hα emitters from the IPHAS observations (see e.g. Viironen et al. 2008): we will consider these
additional samples in following papers (note that most symbiotics have a stellar profile, but a small fraction of them might
be extended in the Hα filter due to their resolved nebulosity, see
Corradi 2003).
symbiotic stars to be used to define our selection method, additional observations were obtained at the INT using the same
instrumental setup as for IPHAS. Photometric data of 18 known
symbiotic stars were taken on June 2, 2004, and April 20, and
September 17 and 18, 2005. Exposure times were tuned so as
to avoid saturation of the (generally bright) targets. Reduction
was done with IRAF. Moreover, existing flux-calibrated spectra
of 18 symbiotic stars (one of which is in common with the sample above), obtained at different epochs, were convolved with
the WFC filters and instrument response curves to derive Hα, r
and i magnitudes in the IPHAS photometric system. Where the
i magnitude cannot be derived from the spectra, we adopted the
r−i colour from Munari et al. (1992). All together, we collected
a sample of 39 known symbiotic stars (29 of the S type and 10
of the D type) with magnitudes and colours fully consistent with
those produced by the photometric catalogue of IPHAS. This
constitutes the primary reference sample to develop our selection method.
We have also investigated other classes of stars and nebulae
which can potentially be confused with symbiotic stars according to their IPHAS colours, because of also having Hα in emission, or because their spectral type is similar to that of the cool
component of symbiotic stars. Using IPHAS and additional observations, we have derived Hα, r and i magnitudes for 67 planetary nebulae (PNe, Viironen et al. 2008), 79 cataclysmic variables (Witham et al. 2006), and 518 Mira variables. As Be stars
are a frequent class of Hα emitting bright stars in the Galactic
plane (cf. Sect. 4.1), they deserve special attention: 18 of these
stars in the low-reddening open clusters NGC 663, NGC 869
and NGC 884, as well as 22 objects in the more reddened cluster NGC 7419, turned out to have good IPHAS photometric data
and were adopted as the comparison samples for this class of
stars. Another frequent class of Hα emitters in star-forming regions are T Tauri stars; their characteristics derived from IPHAS
data on Cyg OB2 are being investigated by Vink et al. (2008).
Finally, Hα emission is also observed in late K to M dwarfs
with enhanced chromospheric and coronal activity (dMe stars).
However, their Hα emission is generally faint, with line equivalent widths1 of a few Å (Hawley et al. 1996). These are much
smaller than in symbiotic stars (see Sect. 4.3), and for this reason
dMe stars are not further considered in this paper.
2.3. Near-IR 2MASS magnitudes
As symbiotic stars contain a luminous cool giant, near-IR magnitudes provide information both on their nature and support
making distinctions between them and other classes of objects. The division in the two main groups of S and D types
was indeed originally made using the J−H and H−K colours
(Allen & Glass 1974). Recently, the position of symbiotic
stars in the near-IR colour–colour diagram was discussed by
Rodríguez-Flores (2006) and Phillips (2007).
We have therefore extracted from the Two Micron All
Sky Survey (2MASS) database the J, H and KS magnitudes of 187 known symbiotic stars, 288 PNe (most of them
from Ramos-Larios & Phillips 2005), 95 cataclysmic variables,
1230 Be stars (1148 of which are from Zhang et al. 2005), 487
T Tauri stars (Dahm & Simon 2005), and 121 Mira variables
(Rodríguez-Flores 2006).
2.2. Reference samples of known objects
1
Unsaturated IPHAS data are available for only four known symbiotic stars from the general catalogue of Belczyński et al.
(2000). They are DQ Ser, V352 Aql, V1413 Aql, and Ap 3-1.
In order to build a meaningful reference sample of known
According to the standard definition, the equivalent width of an emission line would be negative. However, in order to simplify the discussion, in this paper we use a positive sign, so that a larger Hα equivalent
width corresponds to a stronger Hα emission, and to a larger r−Hα
colour.
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I.
411
Fig. 1. IPHAS colour–colour diagram for different classes of objects. The locus of main-sequence and RGB stars is indicated by the solid and
dotted lines, respectively. Two sequences are shown, corresponding to reddening values E(B − V) = 0 (left) and 4 (right), respectively. The arrow
indicates the reddening vector for normal stars: its length corresponds to 3 mag extinction in V.
Similarly, we have searched for 2MASS counterparts of the
4853 Hα emitters in Witham et al. (2008). For 4330 of them, we
found a 2MASS source within 1 arcsec from the IPHAS coordinates (note that the two sets of data are calibrated into the same
astrometric system). Also, the 2MASS counterpart was identified for another 8 objects with slightly worse astrometric match.
This makes a total sample of 4338 Hα emitters with 2MASS
magnitudes.
It should be noted that the detection limits of IPHAS (r ≤
19.5 mag for the objects in Witham et al. 2008) and of the
2MASS point-source catalogue (KS ∼ 15 mag) roughly match
the characteristic colours of symbiotic stars. We have considered
a list of 71 known and bright symbiotic stars (r ≤ 14.5 mag):
70% of them have indeed an observed optical-to-near-IR colour
(r − KS ) ≥ 4.5. On the average, they are presumably closer and
less reddened than the new symbiotics stars that we aim to detect with IPHAS, for which we then expect to be able to find
a 2MASS counterpart. We are therefore confident that adding
2MASS data does not affect the completeness of our search for
symbiotic stars within IPHAS.
the IDS spectrograph, on nights of May 11, June 14, and
September 9, 2006. Grating R300V was used, which gives a reciprocal dispersion of 1.87 Å per pixel of the 2k × 4k EEV detector, and a spectral coverage from 3800 to 8500 Å (these figures
slightly vary from night to night). The slit width was 1.1 arcsec
projected on the sky, providing a spectral resolution of 5 Å.
Exposure times were 30 min for the two brighter sources discussed in Sect. 5, and 2 h for the faintest and more reddened one.
Several spectrophotometric standards were observed during the
night for relative flux calibration. Reduction was performed using the package onedspec in IRAF. Note that the EEV CCD suffers from significant fringing redward of ∼7000 Å, which was
not possible to remove with the calibration frames obtained during those nights. Also, the flux calibration is somewhat uncertain
above 8000 Å because of significant optical aberrations at the
edge of the large format CCD used with IDS.
3. Interpreting the IPHAS and 2MASS colour–colour
diagrams
3.1. The IPHAS colour–colour diagram
2.4. Follow-up spectroscopy
As the present study was progressing, we started a campaign of
spectroscopic follow-up of the Hα emitters detected by IPHAS.
Accordingly a dozen candidate symbiotic stars, selected as described in the next sections, were observed at the INT using
Our primary tool for the selection of candidate symbiotic stars
in the Galactic Plane is the IPHAS r−Hα vs. r−i colour–colour
diagram, which is presented and thoroughly discussed in Drew
et al. (2005). It is shown in Fig. 1 for the various classes of objects considered. In the diagram, the r−Hα axis mainly indicates
412
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I.
Fig. 2. 2MASS colour–colour diagram for different classes of objects. Symbols are the same as in Fig. 1, albeit smaller owing to the larger number
of objects. In addition, T Tauri stars are indicated by empty circles. Like in Fig. 1, the locus of main-sequence and RGB stars is indicated by the
solid and dotted lines, respectively, for reddening values E(B − V) = 0 (lower-left sequence) and 4 (upper-right sequence). The arrow shows the
reddening vector for normal stars corresponding to 3 mag extinction in V.
increasing values of the Hα emission line equivalent width,
while r−i, for normal stars, is essentially a sequence of increasing spectral types and/or reddening. In the figure, the locus
of main-sequence and RGB stars is indicated by the solid and
dotted lines, respectively (Drew et al. 2005). Two sequences are
shown, corresponding to reddening values E(B − V) = 0 (left)
and 4 (right), respectively. The reddening vector for normal stars,
adopted from Howarth (1983) in the same way as by Drew et al.
(2005), is indicated by the arrow: its length corresponds to 3 mag
extinction in V. We note that, as shown by Drew et al. (2005), at
the higher extinctions probed by IPHAS (6 < AV < 12, roughly)
this vector flattens progressively and in a mildly spectral-type
dependent manner.
The positions of the different classes of object are indicated
as follows. Symbiotic stars of the S type are shown as filled circles, and the D types as triangles. In the case that several measurements of the same object obtained at different epochs are
available, we plot the mean colours as the dispersion of symbiotic stars in the graph is anyway large enough to cover their
intrinsic variability. PNe are indicated by crosses; cataclysmic
variables by filled diamonds; Be stars by empty squares; Mira
variables by dots. In all cases, we show the observed colours.
As expected, given their emission-line spectra are superposed on relatively weak continua, PNe stand out in the graph
for their extreme r−Hα colours. Most of them lie close to the
r−Hα ∼ 3.1 limit which is expected for pure Hα emission line
stars (“ideal” sources for which all the flux in the Hα and r
bands comes from the Hα line). With smaller Hα excesses than
PNe (with some overlap), but still above the other classes of Hα
emitters and normal stars, lie the symbiotic stars. They span a
significant range in r−i colour. Be stars and cataclysmic variables are located closer to the locus of main-sequence stars with
some moderate Hα excess (except for Nova Aql 1995, which is
now in the nebular phase and shows a large r−Hα colour). Mira
variables (which only sometimes show the Hα line in emission)
are mainly found at the right of the diagram, owing to their cool
photosphere and frequent large reddening by circumstellar dust.
The class of T Tauri stars is not shown in the figure, as they are
spread all over the diagram above the sequence of normal stars
(e.g. Vink et al. 2008). They show a broad range of spectral types
as well as Hα equivalent widths. The latter are in most cases
smaller than 500 Å (see Fig. 5 in Dahm & Simon 2005), which
is lower than for the most extreme symbiotic stars. Our strategy
to separate them, at least in a statistical sense, from the evolved
stars on which we are focusing our attention in this work, will
be presented in Sect. 4.4.
The symbiotic stars with the smallest r−Hα colours belong
to the rarer subgroup of the yellow symbiotics, containing G-K
giants. Examples are BD-213873, AG Dra and LT Del. Also, the
figure suggests that the D-types have r−Hα colours generally
larger than the S-types, and more similar to PNe. This was already remarked upon in the past (cf. Kenyon 1986), and in fact
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I.
413
the distinction between PNe and some D-type symbiotic stars is
tricky (cf. Corradi 2003). However, our present sample is limited
to ten objects.
Further information on the location of symbiotic stars in the
IPHAS diagram, albeit limited to the r−i colour, can be obtained
from the literature. Munari et al. (1992) published R and I magnitudes for a large sample of symbiotic stars. We have transformed these data to the Sloan system for the INT+WFC, and in
this case we are able to correct for interstellar extinction using
the data in Whitelock & Munari (1992). The resultant range of
intrinsic r−i colours spanned by 56 symbiotic stars of S type
is between −0.1 and +2.8 mag, while the range spanned by
19 D-type systems is even larger, from −0.7 to +3.6 mag.
3.2. The 2MASS colour–colour diagram
The previous section has shown the potential of the IPHAS
colour–colour diagram to separate symbiotic stars from the vast
majority of stars. However, some overlap is present with classes
of Hα sources whose population in the Galactic Plane is much
larger than that of symbiotic stars. In addition, mixing between
classes is inevitably raised in the presence of photometric errors.
The 2MASS J−H vs. H−KS colour–colour diagram provides
an additional resource to refine the selection of symbiotic stars
(Rodríguez-Flores 2006). The various classes of objects, as well
as normal main-sequence and giant stars (Bessel & Brett 1988),
are indicated in Fig. 2 with the same symbols as in Fig. 1. In
addition, we plot here as empty circles 104 classical T Tauri stars
from Dahm & Simon (2005) with an Hα equivalent width larger
than 40 Å (roughly corresponding to the smallest Hα equivalent
width shown by the known symbiotic stars in Sect. 3.1). All these
T Tauri stars belong to the young cluster NGC 2264, which has
a low foreground extinction (AV = 0.22 mag), and is rich in
pre-main sequence Hα emitters (Dahm & Simon 2005). For all
objects we plot the observed colours. As for the IPHAS diagram,
the reddening vector is computed from Howarth (1983) for the
2MASS filters J, H, and Ks : the adopted shifts for a reddening of
1 mag in V are 0.113 and 0.069 for the J−H and H−KS colours,
respectively.
The bulk of PNe occupy a distinct locus at the bottom of the
near-IR diagram (see also Ramos-Larios & Phillips 2005), to the
right of normal stars. Most of the cataclysmic variables and Be
stars are instead clumped closer to the locus of main-sequence
stars. In particular, note the well-defined sequence at the bottom
of the diagram displayed by Be stars, which extends to the right
side of the unreddened main-sequence stars. We will come back
to this important feature in Sect. 4.1.
S-type symbiotic stars, according to their original definition
(Allen & Glass 1974), have colours typical of RGB stars, with
an upper-right tail due to reddening. They form a compact cluster in the diagram, except for few objects. The most extreme
case is UV Aur (a carbon star), which is displaced to the right
of the S-types sequence, toward the broad region which is occupied by T Tauri stars, D-type symbiotic stars, and some extreme
Mira variables. The location of D-type symbiotics is modeled by
Phillips (2007) with a variable combination of stellar and warm
dust continuum emission, plus some extinction. Three objects,
AS 201, V471 Per, and StHA 190, have significantly smaller
J−H colours than the bulk of symbiotics. Again, these are yellow symbiotics, which tend to occupy the bottom part of the locus of symbiotic stars, as in the IPHAS diagram.
Some PNe fall in the region of D-type symbiotic stars.
These are examples of possible misclassified PNe, which might
Fig. 3. The 4338 Hα emitters by Witham et al. (2008) in the IPHAS
(top) and 2MASS (bottom) colour–colour diagrams. The loci of mainsequence and giant stars and the reddening vectors are also indicated
(see Fig. 1 for a detailed explanation).
instead be symbiotic stars with extended nebulae as frequently suggested in the literature (Corradi 1995; Schmeja &
Kimeswenger 2001; Santander-García et al. 2007).
Finally, T Tauri stars form a broad sequence running parallel
to, and on right side of, S-type symbiotics, that extends well into
the locus of the D-type symbiotic stars. Note that T Tauri stars
with smaller equivalent widths than those displayed, including
the so-called weak-line T Tauri stars, would be clumped on the
left-bottom end of this sequence (Dahm & Simon 2005). The
significant overlap with symbiotic stars in both the 2MASS and
IPHAS diagrams, makes T Tauri stars the most frequent “contaminants” in our search for symbiotics stars.
4. Application to the list of IPHAS Hα emitters by
Witham et al. (2008)
The analysis of the IPHAS and 2MASS colour–colour diagrams
presented in the previous section allows us to discuss the nature of the 4338 IPHAS Hα emitters by Witham et al. (2008)
with 2MASS counterparts (Sects. 2.1 and 2.3). Their location
in the colour–colour diagrams is shown in Fig. 3. Looking at
the 2MASS diagram, there are some striking similarities with
414
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I.
Fig. 4. Left: location of known Be stars
in the IPHAS and 2MASS diagrams. The
dots mark dereddened colours for the
1148 Be stars from Zhang et al. (2005).
Open squares are the reddened data for
the open clusters NGC 663, NGC 869
and NGC 884, and filled squares similar data for NGC 7419. The solid line
is the adopted zero-reddening selection
box for Be stars. Right: the 2035 candidate Be stars in the list of 4338 Hα
emitters by Witham et al. (2008). The alternate solid/dotted boxes show the selection boxes (see text) for Av = 0, 2, 4,
6, 8 mag, from bottom-left to top-right,
respectively.
the plot of known objects in Fig. 2. First, the 2MASS diagram of
Fig. 3 shows a main concentration of sources at its bottom, to the
right of the unreddened main-sequence stars. They form a dense
band with a slightly lower inclination than our adopted reddening vector. This is obviously similar to the sequence defined by
known Be stars in Fig. 2. Second, another inclined sequence of
objects can be seen in Fig. 3 at higher J−H values, in the region
where T Tauri stars (frequent in the Galactic Plane) and symbiotic stars (presumably less numerous) should be located.
We therefore start our discussion by considering what appears to be one of the most represented classes of objects in the
list of Witham et al. (2008): the Be stars.
4.1. Be stars
In order to further investigate the similarities between Fig. 2
and 3, we have studied in more detail the location of Be stars
in the colour–colour diagrams. Zhang et al. (2005) provide the
reddening of 1148 individual objects: this allow us to identify
the locus of unreddened Be stars in the 2MASS diagram, and
to define a corresponding “selection” box. These are indicated
by the dots and the solid line, respectively, in the lower-left
panel of Fig. 4. When shifted to the reddening of the clusters
NGC 663, NGC 869 and NGC 884 (AV ∼ 2 mag, dotted line)
and NGC 7419 (AV ∼ 6 mag, dashed line), such a box includes
the corresponding data points for these clusters (empty and filled
squares, respectively).
Similar consistent results are obtained for the IPHAS colour–
colour diagram. There, if we define the locus of Be stars from
the position of the objects in the four open clusters considered,
and correct for the corresponding reddening, we can determine
a zero-reddening selection box for this class of objects, which is
shown as a solid line in the upper-left panel of Fig. 4.
We have then done the exercise of extracting candidate Be
stars from the 4338 IPHAS Hα emitters in Witham et al. (2008).
An object is considered to be a good candidate Be star if it falls
inside the selection boxes in both the IPHAS and the 2MASS
diagrams. The combination of the selection boxes in the two diagrams, shifted so as to consider a range of reddening values
from AV = 0 to AV = 8 mag (represented by the sequence of
boxes in the right panels of Fig. 4), results in a total of 2035 candidate Be stars (also plotted in Fig. 4). The majority of them
would have reddening values between 3 and 5 mag in V. Objects
at zero reddening are virtually absent, presumably because such
objects are in the main nearby and thus bright and saturated in
IPHAS. Only for significant reddening values (i.e. at the largest
J−H colours, cf. the lower-right panel of Fig. 4 with Fig. 2),
mixing of the Be stars candidates with low-reddening T Tauri
stars is possible. An idea of the magnitude of the contamination
can be gained considering that only 4% of the 450 T Tauri stars
in Dahm & Simon (2005), including those with the lowest Hα
equivalent widths, have J−H ≤ 0.55. Adopting this figure, and
the worst possible (and unlikely) scenario that all sources with
J−H > 0.55 in our complete list of 4338 objects are T Tauri stars,
it would be concluded that only one hundred objects of this class
would be expected with a lower J−H colour, at variance with the
more than 1600 Be star candidates (80% of our list) lying below
this colour limit.
A smaller amount of mixing is expected with other, less frequent classes of objects, like CVs, compact PNe, and symbiotic stars. We conclude that somewhere between 1500 and 2000
Hα emitters in Witham et al. (2008) are likely to be Be stars,
which would therefore be the largest class of objects in this list
of IPHAS Hα stars.
4.2. Planetary nebulae
In Sect. 3.1, we remarked on the overlap in the IPHAS diagram
between PNe and symbiotic stars, especially those of the D-type.
On the other hand, the 2MASS colours are generally different,
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I.
Fig. 5. Top: the selection box for symbiotic stars in the IPHAS colour–
colour diagram, superimposed on the reference sample and the locus
of main-sequence and RGB stars (see Fig. 1 for details). Bottom: the
selection boxes for the S-type (continuous line) and the D-type (dashed
line) symbiotics in the 2MASS diagram. Symbols as in Fig. 2.
allowing a neat separation of the two classes of objects (with
notable exceptions which might be related to misclassification).
A search for compact PNe from the list of Witham et al. (2008),
resulting in a few new candidates, and a confirmation of their
nature by spectroscopic observations, is presented elsewhere
(Viironen et al. 2008).
4.3. Symbiotic stars
In a similar way as done for Be stars, based on the properties of
our reference samples, we define selection boxes in the colour–
colour diagrams to be used for our search for symbiotic stars in
the Milky Way.
In the IPHAS diagram, the limited number of symbiotic stars
of the D-type in the reference sample, as well as their significant
overlap with the S-types (with possible differences, however, as
outlined in Sect. 3.1), prevent us from defining separate boxes
for the two classes. We prefer instead to use the same selection
criterion, leaving to the near-IR colours the task of separating
the two classes according to the original definition. Our selection box for symbiotic stars (Fig. 5, upper panel) is then defined
415
as follows. In the r−i axis, we allow the range of intrinsic colours
spanned by known objects as discussed at the end of Sect. 3.1,
and extend it to the right side of the graph to allow for the significant extinction that is expected when observing through the
Galactic Plane.
In the vertical direction, we define a lower limit which is
an inclined line, parallel to the reddening vector (Sect. 3.1), and
defined by the formula (r − Hα) ≥ 0.25 · (r − i) + 0.65, which
includes all known symbiotic stars in the samples of Sect. 3.1
except for the yellow symbiotic BD-213873. This limit roughly
corresponds to Hα equivalent widths of 50 Å (Drew et al. 2005).
We decided to fix the lowest side of the selection box at this limit
in order to avoid significant mixing with Be stars (see Sect. 4.1).
The upper limit of the selection box for symbiotic stars is the
r−Hα value for pure Hα emitters, namely r−Hα ∼ 3.1.
In the 2MASS diagram, the large number of objects available
allows us to define separate boxes for the S and D-type symbiotic
stars. For the S-types, we first set the lower limit for the J−H
colour which includes all known objects. Then the left and right
limits for the H−KS colours were chosen to run parallel to the
reddening vector. They are chosen to include the vast majority of
S-type systems, except for nine objects (7% of the whole sample)
that are detached and on the right side – these will, in any case,
be included in the selection box for D-types. We have decided
to keep the right limit for S-types (the most frequent class of
symbiotics) as leftward as possible, in order to minimize mixing
with T Tauri stars (even if at the expense of the D-types). The
selection box for S-type symbiotic stars is indicated by the solid
line in the lower panel of Fig. 5. For the D-types, we use the
same procedure, with the further assumption of setting the same
lower limit for the J−H colour as for the S-types, and the H−KS
left limit so as to have contiguous boxes with no gap or overlap.
The selection box for the D-type symbiotics is indicated by a
dashed line in Fig. 5.
In this way, the three yellow symbiotics AS 201, StHA 190,
and V471 Per, fall out of both boxes in the 2MASS diagram.
But they are located in the very populated region of the diagram
where not only main sequence stars are found, but also other Hα
emitters like Be stars and cataclysmic variables. With so much
mixing, a search for this kind of object becomes very difficult.
When our selection criteria are applied to the list of
Witham et al. (2008), 337 sources fall in both the IPHAS and
2MASS selection boxes for the S-types (Fig. 6, left), and 846
fulfill the criteria to be considered D-type candidates (Fig. 6,
right). The complete list of all these candidates is reported in
Table 1, which is only available electronically. In the 2MASS
diagram, a good number of objects fall in the lower right part of
the selection boxes for S-type symbiotic stars, while most of the
objects in the D-type box fall in its left-bottom side. These are
the regions where T Tauri stars are also expected to be found,
indicating that significant mixing of the two classes of objects is
likely to be present in the candidate list (Table 1).
Our selection method recovers the three known symbiotic stars included in the list of Witham et al. (2008), as
well as two suspected ones. Out of the 29 objects listed by
Witham et al. (2008) as known young stellar objects, 13 are included in the list of D-type candidate symbiotics, and 3 in the list
of S-type candidates (note that none of them is classified as a Be
star). This confirms that the mixing with young stellar objects is
more severe for the D-types. Among the 9 known or newly discovered PNe included in the list of Witham et al. (2008), only
one enters the list of D-type candidates. Its nature will be discussed in Viironen et al. (2008).
416
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I.
Fig. 6. Left: the 337 objects with
IPHAS and 2MASS colours fulfilling our selection criteria for S-type
symbiotic stars. The locations of the
three new symbiotic stars discovered by
IPHAS, for which we present spectroscopic confirmation in Sect. 5, are indicated by the circles. Right: the 846 candidate D-type symbiotic stars.
Note that if the lowest edge of the IPHAS selection box is
lowered so as to include all known symbiotic stars in our samples, then another 152 candidates of S-type, plus 330 of D-type,
would be added. At the same time, the confusion with other
classes of object would also increase. In this respect, we stress
that our aim is not to define absolute limits for the colours of
symbiotic stars, but only to provide a practical way of selecting new candidates from the IPHAS survey, guided by the best
reference samples that we were able to build from the literature, IPHAS itself, and from additional observations obtained
in backup time during our observational campaign. As demonstrated below, the proposed selection method seems indeed to be
promising.
4.4. Clustering as an additional criterion to separate young
stars from symbiotics
Observations targeting a narrow band of the Galactic Plane must
include a large number of star-forming regions, young clusters
and associations. There, numerous objects, especially Be and
T Tauri stars, are Hα emitters. We have shown that while Be stars
can be separated from symbiotic stars because of their smaller
r−Hα and J−H colours, T Tauri stars overlap with symbiotics
in both the IPHAS and 2MASS diagrams. Therefore, they must
be regarded as the most serious “contaminants” in our search for
symbiotic stars using IPHAS and 2MASS data.
Our strategy for tackling the problem is to consider the spatial distribution of the Hα emitters selected by IPHAS. T Tauri
stars are expected mainly to be concentrated in young clusters.
On the other hand, symbiotic stars, which belong to an older
Galactic stellar population (bulge/thick-disc, Munari & Renzini
1992), should be more isolated Hα sources (except for projection
effects through the Galactic Plane).
A first step in exploring this issue was taken by measuring the degree of clustering of the objects in the list of
Fig. 7. Histogram of the mean distance to the four most nearby objects
for each of the 4853 Hα emitters by Witham et al. (2008). 29 young
stellar objects are indicated by the short lines at the top of the diagram,
while 20 PNe and symbiotic stars are indicated by the dots.
Witham et al. (2008). For each of the 4853 Hα emitters, the
mean distance to the n most nearby objects (with n from 1 to
12) was computed. We show in Fig. 7 the distribution of the distances for n = 4, that we find to be a good compromise between
having a sufficient number of neighbours to detect the existence
of a group, while avoiding the limited statistics that the requirement of a large number of neighbours might suffer from, given
the size of the global sample.
The 29 objects listed by Witham et al. (2008) as young stellar objects, as well as 20 known, suspected or confirmed new
PNe (Viironen et al. 2008) and symbiotic stars (to be presented
in Paper II) were then considered. They confirm the expected
trend: young stars (the vertical short lines at the top of Fig. 7)
tend to occur with smaller angular separations than do PNe and
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I.
417
Fig. 8. Spectra of the first three new symbiotic stars discovered by IPHAS. The region around 7600 Å with the strong oxygen atmospheric
absorption band is not plotted. The main low and high excitation emission lines and the heads of the TiO bands, which demonstrate the symbiotic
nature of the objects, are labeled. The oscillations in the very red part of the spectra are due to fringing in the detector.
symbiotic stars (the filled circles). Therefore, this additional parameter seems to be a useful one to distinguish, at least in a statistical sense, young stellar objects from stars belonging to older
Galactic populations like symbiotic binaries. We expect that the
significance of this parameter will improve further as the sample of Hα emitters detected by IPHAS grows in number; this
would allow a better definition of clustering in the area observed
by IPHAS. For the time being, we add the mean distance to the
four nearest neighbours as a further datum in the list of candidate symbiotic stars in Table 1; the weight to be given to this
parameter is left to the discretion of the user. In any case, we
note that about 50% of both the S-type and D-type candidates
in Table 1 have a mean distance to their four nearest neighbours
that exceeds 15 arcmin: these candidates are our preferred initial
targets for spectroscopic follow-up.
5. Spectroscopic confirmation: the first symbiotic
stars discovered by IPHAS
As an illustration of the potential of IPHAS and the selection
method proposed in the previous sections, we present here the
spectra of the first three new symbiotic stars discovered by
IPHAS. Data for more stars and a deeper analysis of the individual objects will be presented in Paper II.
In the following, we use both the standard nomenclature for
IPHAS point sources (“IPHAS J” followed by the J2000 coordinates, see Drew et al. 2005), as well as the name “IPHAS-Sy
nn” to indicate the nnth symbiotic star discovered by the survey.
The INT spectra are shown in Fig. 8, and the location of
the objects in the IPHAS and 2MASS diagrams is indicated by
open circles in Fig. 6. The three objects have large r−Hα colours
418
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I.
and fall in the selection box for S-type symbiotics. In the latter,
two of them have colours characteristic of strongly reddened red
giants, as confirmed by the INT spectra.
5.1. IPHAS J185704.44+002631.7 (IPHAS-Sy 1)
The IPHAS and 2MASS magnitudes of IPHAS-Sy 1 are: r =
18.28, i = 16.03, Hα = 15.59, J = 10.42, H = 8.86, and KS =
8.09. No objects are listed in the SIMBAD database, within a
radius of 2 arcmin about the source coordinates, and the nearest
known radio HII detection is over 30 arcmin away. There is no
evidence to link this object to a known star-forming region.
The Hα equivalent width is 800 Å, which corresponds to
r−Hα = 2.69. This is the faintest objects of the three in the optical (but not in the near-IR), and the one with the highest J−H
colour. This can be mainly ascribed to reddening, as shown by
the steep decrease of the flux below 5000 Å (no emission is detected blueward of the [OIII]5007 Å line) and the large r − KS
colour amounting to 10.2 mag. The symbiotic nature of IPHASSy 1 is indicated by the simultaneous presence of high excitation emission lines of [OIII] and [ArIII], and the TiO absorption
bands of a M-type star (Fig. 8, upper panel).
5.2. IPHAS J190924.64-010910.2 (IPHAS-Sy 2)
IPHAS-Sy 2 has the following magnitudes: r = 17.16, i = 15.26,
Hα = 14.79, J = 11.44, H = 10.29, and KS = 9.80. Its Hα
equivalent width is 650 Å (r−Hα = 2.38).
In SIMBAD, it is indicated as a possible PN (K 4-17), but
the spectrum described by Stenholm & Acker (1987) does not
allow its real nature as a symbiotic star to be identified. This
is instead revealed by our INT spectroscopy, which captures a
rich set of high excitation emission lines ([NeIII], [OIII], HeII,
and even [FeVII]), accompanied by the red continuum of an M4
giant (Fig. 8, middle panel). No star formation regions are catalogued in the vicinity of IPHAS-Sy 2.
5.3. IPHAS J202510.58+435233.0 (IPHAS-Sy 3)
Its magnitudes are: r = 15.34, i = 13.34, Hα = 13.42, J = 9.94,
H = 8.45, and KS = 7.73. The Hα equivalent width is 250 Å
(r−Hα = 1.92).
IPHAS-Sy 3 is listed in SIMBAD as a misclassified
planetary nebula (PN K 3-59), but the spectrum of
Sabbadin et al. (1987) only reveals weak Hα line emission
superimposed on a very red continuum. Our observations show
the composite spectrum defining a symbiotic star, with the
simultaneous presence of the continuum of an early M star and
high excitation emission lines.
In projection, the star is located in the Cygnus X complex, a little over 3 arcmin from the HII region DWB 137
(Dickel et al. 1969). The vicinity of young stars might cast some
doubt on the nature of IPHAS-Sy 3 as a symbiotic star. Even if
it shows some of the typical spectral signatures of these interacting binaries, such as the TiO bands together with highly ionized
HeII and [OIII] in emission, some extreme examples of T Tauri
stars also present them (see e.g. Beristain et al. 2001).
However, there are several arguments pointing toward
IPHAS-Sy 3 as most likely being a symbiotic star. First, its spectrum lacks evidence of other features typical of T Tauri stars: e.g.
the strongest resonance Li doublet at 6708 Å in absorption; any
of FeII or NaI lines in emission; apparent broadening of the HeI
emission line profiles. Second, T Tauri stars, being closer to the
main sequence (MS), have radii just 2−3 times larger than their
MS descendants, whereas symbiotic stars must contain a red giant with radii two orders of magnitudes larger than MS values.
Playing devil’s advocate, we can see if a typical T Tauri star radius works for IPHAS Sy 3 if placed at a plausible distance to
be in a young Cygnus-X cluster. The distance to the young cluster containing the Herbig Be star V1685 Cyg, some 3 degrees
away on the sky, is given as 980 pc (Davies et al. 2001), with the
other nearby HII regions in Cygnus X being mostly at 1–2 kpc
(Straizys et al. 1993). For a distance of ∼1 kpc, an M0 spectral
type (compatible with the strength of the TiO and VO absorption bands), a reddening E(B − V) ∼ 2−2.5 (estimated from HI
and HeI emission line ratios, the J − KS colour, and a fit of the
optical and near-IR spectral energy distribution), we apply the
Barnes-Evans relation (e.g. Beuermann et al. 1999) to derive a
radius ∼30 R⊙ . This is too large for a T Tauri star, but consistent
with the presence of a red giant. The estimated radius increases
if the distance is larger than 1 kpc.
6. Summary and perspectives
Searching for a relatively rare and old family of stars in a narrow
band in the Galactic plane, where young stellar objects dominate
the population of Hα emitters, might seem a hard challenge. Our
motivation to embark in such an enterprise is the poor knowledge of the total population of symbiotic stars in the Galaxy: the
IPHAS survey gives us the opportunity to tackle this problem by
performing, for the first time, a complete search of these objects
in a magnitude limited volume.
As symbiotic systems contain a cool giant star, the near-IR
data from the 2MASS survey have been added to the IPHAS
photometry. Then, a discussion of the location of the different
classes of Hα emitters in the combined IPHAS and 2MASS
colour–colour diagrams has been presented. This allows us to
define selection criteria for symbiotic stars which separate them
from the vast majority of normal and Hα emitting stars.
The only exception are T Tauri stars. They overlap with symbiotic stars in the IPHAS diagram. In the 2MASS one, they
form a sequence very close to (and partially overlapping with)
the main subclass of symbiotic stars (S-types), and fully overlap
with the other, less frequent group of symbiotics (the D-types).
In fact, even when a spectrum is available (see Sect. 5.3), it is
sometimes difficult to distinguish a symbiotic star from those
T Tauri stars which display high excitation emission lines. As
an additional criterion to separate symbiotic from T Tauri candidates in our survey, we have considered the spatial distribution
of the Hα emitters detected by IPHAS. T Tauri stars are expected
to be found in groups in star forming regions. In contrast, symbiotic stars should be more isolated objects. With this aim, we
have introduced a “clustering” parameter which is the mean distance to the four most nearby Hα emitters in the IPHAS list that
we have considered (Witham et al. 2008).
We expect that all these criteria for the search for symbiotic
stars within IPHAS will improve as soon as additional information is gathered from the survey itself. A better fix on the number
of Hα emission line stars above specified, more exacting equivalent width thresholds, might improve our estimates of the clustering parameter – or further follow-up spectroscopy of the selected candidates can improve our understanding of the IPHAS
and near-infrared colour–colour planes.
With this second aim in mind, we have started an intensive
spectroscopic campaign. With it, we hope that the number of
symbiotic stars in the IPHAS area, so far limited to only 11
objects listed in the catalogue of Belczyński et al. (2000), will
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I.
significantly increase. The confirmation in this paper of three
new systems out of a small sample of candidates observed in the
first nights of the spectroscopic follow-up, seems to be a good
start in this direction.
Acknowledgements. We are grateful to many of our collaborators in the IPHAS
project, for continuous discussion about the properties of the variety of objects
that are involved in the analysis of the survey data. R.L.M.C., E.R.R.F., A.M.,
and K.V. acknowledge funding from the Spanish AYA2002-0883 grant, and JM
funding from Polish KBN 1PO3D 017 27 grant.
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Munari U., 1997, in Physical processes in Symbiotic binaries and related systems, ed. J. Mikolajewska, Copernicus Found. for Polish Astron., Warsaw,
37
Munari, U., & Renzini, A. 1992, AJ, 397, 87
Munari, U., Yudin, B. F., Taranova, O. G., et al. 1992, A&AS, 93, 383
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preparation
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Zhang, P., Chen, P. S., & Yang, H. T. 2005, New Astron., 10, 325
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 1
Table 1. 1183 candidate symbiotic stars extracted from the list of Witham et al. (2008) using the photometric constraints defined in Sect 4.3.
Columns contain: the coordinates, the IPHAS and 2MASS magnitudes, and the mean distance d4 (in arcmin) from four neighbours (see Sect. 4.4).
Part A contains the candidate S-type symbiotics, and Part B the candidate D-types.
RA (J2000.0) Dec
Part A: S-type candidates
00 07 40.09 +65 40 10.6
00 08 34.71 +65 28 32.8
00 10 33.27 +58 40 21.1
00 10 36.41 +58 50 05.0
00 13 01.79 +65 34 45.7
00 14 28.55 +65 49 34.5
00 15 20.95 +65 49 41.1
00 15 22.04 +65 45 30.4
00 19 09.80 +62 34 01.5
00 21 06.03 +62 10 49.1
00 22 05.18 +62 36 11.1
00 27 18.55 +64 44 31.3
00 30 31.28 +65 32 02.1
00 30 47.88 +65 21 22.1
00 31 52.06 +65 28 08.3
00 34 24.83 +65 59 30.9
00 36 01.76 +62 32 35.6
00 39 27.23 +60 19 00.3
00 41 10.36 +62 10 54.0
00 41 53.24 +61 49 42.8
00 42 12.35 +61 54 43.2
00 42 52.37 +61 10 39.3
01 23 05.28 +61 42 00.8
01 23 41.80 +61 50 01.0
01 27 01.54 +62 33 07.3
01 38 37.90 +64 57 47.3
02 23 07.88 +56 58 07.2
02 27 59.30 +58 51 47.9
02 28 16.91 +62 09 50.8
02 29 01.93 +62 07 25.2
02 31 42.96 +61 04 53.0
02 32 51.54 +61 43 46.8
02 32 53.77 +62 15 28.9
02 36 57.74 +61 28 57.1
02 37 01.50 +61 28 23.6
02 37 49.30 +60 51 07.3
02 38 14.81 +61 52 14.6
02 41 48.15 +57 23 37.1
02 50 45.30 +60 28 09.4
02 52 11.62 +60 29 51.5
02 52 48.11 +60 16 09.6
02 55 26.52 +57 20 50.6
02 57 19.80 +60 21 41.3
02 57 49.09 +60 46 17.9
02 58 20.50 +60 35 58.4
02 58 45.13 +60 29 42.1
02 59 17.69 +60 34 11.0
02 59 31.03 +60 40 25.5
03 00 07.58 +60 25 36.8
03 00 43.98 +60 30 59.0
03 11 47.12 +56 34 30.2
03 17 04.34 +60 15 00.0
03 19 37.54 +59 11 14.4
03 20 20.46 +60 16 32.9
03 20 46.82 +60 20 33.0
03 20 48.19 +60 20 19.0
03 25 42.41 +58 57 30.0
03 26 47.39 +58 55 38.3
r
i
Hα
J
H
Ks
d4
17.07
18.54
16.00
14.66
18.89
19.42
18.59
16.68
19.16
19.37
18.57
19.48
18.51
18.65
18.38
17.69
18.56
18.67
17.72
18.15
17.31
18.24
18.24
17.24
19.26
17.97
18.35
19.20
18.67
18.81
19.30
18.69
17.70
18.26
17.90
19.24
18.23
19.03
18.04
18.41
18.71
18.07
19.47
18.78
18.95
19.12
19.43
18.75
19.08
18.76
18.76
16.65
18.82
18.59
17.96
16.70
18.68
17.95
15.80
17.06
14.40
13.70
17.23
17.32
16.61
15.49
17.82
17.93
17.06
17.95
16.84
17.00
16.94
16.12
17.18
17.55
15.59
16.23
15.33
16.62
16.83
15.99
17.83
16.59
17.43
18.00
17.46
17.72
18.10
17.48
16.76
16.96
16.73
17.99
17.13
17.85
16.80
17.20
17.54
16.85
18.20
17.62
17.72
17.80
17.90
17.54
17.91
17.55
17.29
15.33
17.43
17.12
16.58
15.59
17.21
16.51
15.56
17.12
14.51
13.06
17.00
17.82
17.14
15.13
17.97
18.33
17.54
18.21
16.79
17.58
17.24
16.57
17.39
17.62
16.44
16.82
15.92
16.90
16.96
16.26
18.06
16.75
17.42
17.48
17.49
17.42
18.29
17.26
16.71
17.24
16.67
18.08
17.06
17.87
17.01
17.38
17.20
17.09
18.21
17.76
17.69
17.96
18.16
17.36
17.84
17.53
17.42
15.21
17.64
17.17
16.69
15.51
17.43
16.60
13.98
14.75
12.34
11.89
14.72
15.11
14.28
13.47
16.10
15.99
14.45
15.30
14.71
14.32
14.95
13.47
14.76
15.89
13.38
13.89
12.85
14.04
14.80
13.77
15.24
14.61
15.47
15.93
15.38
15.78
16.13
15.20
15.10
15.04
14.72
15.99
15.21
16.30
14.76
15.30
15.35
14.77
16.37
15.61
15.67
15.49
15.53
15.25
15.70
15.45
14.94
13.33
15.31
14.89
14.63
13.63
15.26
14.05
13.14
13.87
11.45
11.09
13.80
14.19
13.36
12.54
15.34
14.94
13.39
14.23
13.65
13.20
13.82
12.36
13.52
14.99
12.60
13.03
12.07
12.99
13.96
12.75
14.16
13.57
14.73
14.85
14.35
14.92
15.15
14.23
14.25
13.94
13.67
14.83
14.38
15.34
13.74
14.34
14.25
13.93
15.34
14.72
14.61
14.66
14.46
14.15
14.56
14.43
13.77
12.35
14.36
14.07
13.62
12.74
14.39
12.89
12.84
13.55
11.00
10.74
13.38
13.78
12.98
12.09
15.17
14.55
13.08
13.72
13.16
12.61
13.34
11.82
12.91
14.66
12.25
12.64
11.71
12.58
13.68
12.26
13.83
13.06
14.49
14.30
13.86
14.64
14.89
13.74
13.96
13.53
13.17
14.26
14.11
14.93
13.27
14.01
13.78
13.58
15.01
14.38
14.07
14.29
13.98
13.63
14.12
13.97
13.26
11.91
14.05
13.69
13.13
12.38
14.05
12.31
6.7
10.8
4.7
7.2
15.2
5.8
6.1
6.2
11.6
17.9
14.1
22.6
4.6
6.9
8.3
25.3
33.7
33.4
20.2
9.3
7.7
6.1
14.6
15.1
19.2
28.4
34.0
28.3
14.1
17.3
10.3
7.6
20.6
10.5
10.8
14.9
11.3
15.3
10.3
8.2
7.5
25.5
10.7
6.7
4.8
4.4
2.8
5.0
4.4
3.8
29.1
11.8
25.4
4.1
4.2
4.1
14.5
9.1
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 2
Table 1. continued.
RA (J2000.0) Dec
03 32 32.97 +60 08 25.2
03 43 35.34 +53 09 40.6
03 44 22.86 +54 07 29.0
03 44 23.39 +56 46 36.3
03 59 22.23 +51 54 15.1
04 02 32.14 +51 39 58.1
04 07 32.70 +57 38 31.4
04 16 42.06 +55 14 44.2
04 23 34.84 +50 18 22.5
04 26 04.19 +45 34 22.7
04 29 07.66 +45 26 47.1
04 31 00.52 +44 55 59.6
04 36 29.20 +45 17 50.4
04 47 07.00 +43 43 39.0
04 56 30.88 +43 57 48.9
04 56 38.58 +45 02 25.9
05 03 15.64 +43 41 43.5
05 11 05.67 +42 36 21.3
05 12 01.82 +38 43 34.0
05 18 27.42 +30 08 49.7
05 20 53.15 +38 08 45.8
05 22 41.49 +33 20 50.1
05 22 45.78 +33 28 16.4
05 23 00.06 +33 30 39.0
05 25 44.57 +34 50 17.9
05 26 30.69 +34 50 14.8
05 26 52.58 +40 33 06.2
05 27 12.33 +34 32 19.8
05 27 16.23 +35 13 39.6
05 27 25.89 +34 42 41.7
05 27 43.83 +34 40 27.9
05 27 54.45 +34 46 22.2
05 27 54.76 +34 45 30.7
05 30 18.12 +31 35 58.9
05 32 58.06 +25 54 37.8
05 34 06.31 +25 38 22.5
05 34 26.31 +25 38 50.4
05 34 56.79 +27 47 36.4
05 36 11.81 +32 14 37.9
05 36 12.82 +27 34 10.8
05 36 41.46 +31 46 27.8
05 37 14.05 +27 48 57.8
05 38 44.29 +26 16 41.7
05 39 11.84 +26 42 18.8
05 39 29.60 +31 23 49.5
05 40 50.08 +35 23 49.1
05 42 23.90 +22 49 15.4
05 43 33.43 +33 24 11.8
05 47 06.78 +20 59 13.0
05 49 14.66 +33 23 29.3
05 52 04.78 +20 07 33.8
05 58 37.29 +32 04 38.1
05 58 45.75 +20 10 12.6
05 59 36.44 +20 31 49.0
06 00 05.82 +20 18 17.8
06 01 34.22 +16 13 45.8
06 08 21.91 +29 52 55.7
06 11 20.03 +13 20 58.1
06 13 08.11 +23 05 23.1
06 13 17.70 +23 08 14.1
06 13 28.37 +16 04 55.1
r
18.93
18.25
18.64
18.51
17.09
18.20
16.74
18.59
18.39
19.26
18.42
19.25
18.08
18.30
18.84
15.08
15.91
18.18
18.97
13.76
19.06
18.44
18.30
17.07
17.73
17.94
18.86
18.99
19.01
18.15
18.82
17.29
18.50
16.95
17.86
17.29
19.25
18.00
16.92
18.09
18.19
18.89
17.58
17.07
18.55
17.70
19.15
18.44
18.68
16.97
17.20
19.32
17.79
19.01
19.11
15.37
17.80
18.96
17.77
17.74
18.11
i
17.31
16.72
17.32
17.15
16.09
16.78
15.73
17.90
17.22
17.64
17.53
18.02
16.86
17.07
17.40
14.30
14.90
16.87
18.03
12.40
17.78
17.39
17.06
16.13
16.63
16.97
17.91
18.05
17.77
17.22
17.84
16.55
17.49
16.02
16.30
16.21
17.44
16.95
16.10
16.60
16.90
17.46
16.15
15.89
17.21
16.41
17.87
17.51
17.02
16.01
16.29
18.28
16.77
17.61
17.59
14.44
16.35
17.75
17.64
17.67
16.37
Hα
17.77
17.13
17.19
17.41
16.12
17.14
15.74
17.18
17.42
17.71
17.28
18.13
17.04
17.24
17.77
14.12
14.73
17.13
17.93
12.70
18.05
17.42
17.19
16.14
16.76
16.86
17.90
17.80
17.81
16.99
17.30
16.30
17.49
16.01
16.55
16.11
17.43
17.00
15.51
16.96
17.10
17.64
16.36
16.11
17.00
16.49
17.73
17.41
17.35
15.74
16.25
18.38
16.76
17.82
18.04
14.21
16.39
17.78
16.86
16.23
16.46
J
14.84
14.37
15.09
15.27
14.35
14.75
14.05
16.51
15.51
15.22
15.67
16.09
15.18
15.44
15.31
12.90
12.16
15.39
15.70
10.59
15.49
15.54
15.05
14.34
14.71
15.26
16.33
16.12
15.85
15.44
16.12
15.23
15.36
14.32
14.32
14.10
14.98
15.10
14.68
14.10
14.91
15.24
14.25
14.19
15.10
14.44
15.97
15.97
14.93
14.32
14.84
16.44
14.95
15.58
15.51
12.98
14.41
15.70
15.45
15.27
13.74
H
13.80
13.29
14.06
14.41
13.54
13.68
13.23
15.77
14.34
13.95
14.96
14.84
14.31
14.62
14.37
12.09
11.46
14.67
14.67
9.89
14.47
14.38
14.04
13.42
13.72
14.21
15.48
15.25
14.59
14.59
15.36
14.49
14.39
13.50
13.42
13.10
14.09
14.24
13.96
12.89
13.93
14.12
13.43
13.39
14.14
13.50
14.62
15.07
13.83
13.47
14.08
15.70
14.11
14.62
14.62
12.28
13.37
14.68
14.59
14.49
12.93
Ks
13.32
12.86
13.76
14.19
13.37
13.24
13.02
15.48
13.74
13.28
14.68
14.46
14.04
14.36
13.96
11.71
11.15
14.49
14.24
9.64
14.10
13.91
13.54
12.97
13.23
13.74
15.22
15.01
14.10
14.31
15.08
14.22
13.91
13.21
13.09
12.59
13.71
13.88
13.68
12.29
13.57
13.69
13.18
13.19
13.75
13.09
14.02
14.64
13.34
13.12
13.84
15.40
13.90
14.30
14.34
12.04
12.84
14.16
14.34
14.12
12.58
d4
20.7
37.9
30.6
32.5
13.5
25.5
20.4
23.2
41.5
29.4
9.2
27.3
18.7
24.7
40.2
36.5
34.1
35.9
12.9
65.0
51.8
7.4
3.5
3.7
10.3
7.4
54.9
5.8
15.7
4.7
3.2
3.8
3.2
33.7
20.1
9.9
8.9
13.2
13.6
12.7
4.5
7.0
21.4
21.5
27.7
21.8
31.7
34.8
40.0
20.1
65.1
34.3
11.4
12.4
9.2
22.9
44.2
42.9
19.7
20.2
28.5
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 3
Table 1. continued.
RA (J2000.0) Dec
06 14 19.39 +21 28 05.7
06 15 40.34 +19 00 05.2
06 16 48.63 +20 56 33.1
06 16 56.26 +23 38 27.1
06 22 06.53 +22 34 36.7
06 31 24.23 +12 16 12.7
06 31 41.98 +04 54 18.2
06 31 54.87 +10 31 18.8
06 31 58.90 +04 58 11.1
06 32 05.29 +04 57 42.5
06 32 10.04 +12 08 17.8
06 32 16.30 +10 09 55.9
06 36 12.36 +03 43 33.7
06 36 59.97 +02 09 58.9
06 37 01.68 +02 10 46.7
06 37 03.18 +02 10 13.9
18 29 06.08 -00 34 57.2
18 33 34.49 +00 34 22.1
18 35 01.83 +01 46 56.0
18 37 48.03 -00 16 17.2
18 38 07.38 +00 11 13.6
18 39 43.08 -01 11 16.7
18 44 39.63 +05 02 49.1
18 44 46.08 +06 07 03.5
18 46 28.35 +00 25 54.5
18 47 33.03 +03 25 54.3
18 48 39.34 +00 23 42.9
18 50 39.20 +06 59 16.7
18 53 23.58 +08 49 55.1
18 56 07.26 +00 38 22.9
18 57 04.44 +00 26 31.7
19 01 06.87 +04 59 27.5
19 03 09.13 +02 04 31.8
19 03 56.19 +09 01 58.4
19 04 41.53 -00 59 57.2
19 09 24.64 -01 09 10.2
19 10 36.14 +02 49 28.2
19 19 17.89 +20 30 51.6
19 21 26.35 +10 53 40.2
19 22 04.55 +10 31 53.7
19 23 36.01 +10 00 09.4
19 25 06.46 +22 45 14.1
19 25 15.05 +22 47 20.3
19 25 56.60 +23 04 54.0
19 26 29.11 +21 04 07.4
19 26 35.81 +22 39 24.4
19 27 12.25 +22 39 36.9
19 27 42.36 +20 18 25.7
19 29 51.43 +21 54 11.3
19 34 36.06 +16 31 28.9
19 35 01.31 +13 54 27.5
19 35 30.04 +27 11 47.6
19 41 17.05 +22 01 32.3
19 41 20.78 +24 56 12.8
19 42 23.61 +22 55 30.8
19 44 50.12 +23 47 22.5
19 45 23.91 +23 55 13.1
19 45 29.73 +24 11 56.5
19 59 10.60 +29 19 40.3
20 02 23.56 +35 16 56.3
20 04 21.29 +35 41 49.6
r
18.28
18.49
18.84
19.09
18.61
18.74
16.45
17.84
18.16
17.18
19.07
18.12
18.09
18.82
17.41
18.56
17.53
18.01
16.34
16.94
18.47
17.79
14.01
14.74
18.32
18.55
15.54
17.93
16.54
17.46
18.28
18.73
18.85
16.33
15.88
17.16
15.32
18.14
18.39
19.00
18.71
16.24
16.40
17.73
15.18
18.00
16.56
18.43
18.33
16.84
14.04
17.35
18.68
14.91
19.41
19.05
17.91
19.02
16.38
18.77
19.10
i
17.64
17.36
17.61
17.97
16.86
17.65
15.58
15.74
17.06
16.24
17.83
16.09
16.88
17.38
16.08
17.11
14.87
16.05
14.47
15.51
17.08
16.30
12.27
13.34
16.81
15.32
14.43
15.74
14.25
15.73
16.03
16.66
17.53
14.54
13.08
15.26
12.79
16.37
16.03
16.32
16.57
15.12
15.29
16.08
14.15
16.36
15.11
16.67
17.09
14.65
12.51
15.58
16.89
13.30
18.04
17.75
16.50
17.71
14.43
17.23
17.95
Hα
16.74
17.39
17.48
17.66
17.40
17.66
15.56
16.62
16.89
16.01
18.01
16.70
16.79
17.27
16.43
17.32
15.66
16.82
13.83
15.72
16.11
16.71
12.67
12.70
17.04
16.14
14.47
16.57
14.28
16.17
15.59
17.04
17.66
15.21
14.19
14.79
13.50
16.72
16.46
16.66
17.34
14.99
14.60
16.51
14.26
16.68
15.46
17.18
17.34
14.49
12.81
16.05
17.19
13.77
18.30
18.02
16.88
17.89
15.14
17.50
17.63
J
15.55
15.40
15.64
15.81
14.48
15.88
13.89
12.85
15.09
14.61
15.78
13.51
14.84
15.03
14.06
14.40
10.97
13.24
10.74
13.25
14.20
13.93
9.39
11.04
14.31
10.07
12.48
12.31
10.32
13.11
10.43
13.87
15.23
14.78
8.89
11.44
10.08
14.13
12.61
11.89
14.52
13.43
13.38
14.31
12.69
13.89
12.95
14.40
15.08
10.71
10.05
14.24
14.61
10.39
15.62
15.62
14.21
16.00
11.04
14.76
15.56
H
14.75
14.45
14.58
14.66
13.37
14.95
13.18
11.75
14.19
13.78
14.67
12.74
13.71
13.90
13.12
13.21
9.61
12.09
9.48
12.31
13.24
12.99
8.29
9.88
13.08
8.44
11.57
10.86
9.04
12.00
8.86
12.89
14.21
14.00
7.75
10.29
8.94
13.13
11.52
9.98
13.70
12.51
12.57
13.57
11.92
12.75
11.83
13.64
14.29
9.34
8.98
13.49
13.75
9.19
14.34
14.42
13.10
14.74
9.67
13.75
14.65
Ks
14.56
14.06
14.15
14.15
12.93
14.73
12.90
11.24
13.74
13.50
14.16
12.38
13.15
13.37
12.72
12.58
9.05
11.63
8.92
12.04
12.79
12.68
7.81
9.41
12.46
7.71
11.25
10.32
8.52
11.44
8.09
12.44
13.74
13.71
7.17
9.80
8.51
12.79
10.95
9.04
13.40
12.05
12.24
13.38
11.70
12.21
11.31
13.35
14.11
8.77
8.58
13.40
13.44
8.73
13.66
14.01
12.56
14.28
9.10
13.23
14.22
d4
27.4
31.0
36.0
33.4
10.2
32.1
4.4
8.5
4.7
4.9
37.0
5.6
38.8
3.6
3.6
3.9
51.1
40.0
26.4
42.7
36.0
46.5
53.1
44.5
25.9
54.0
38.9
65.7
85.5
23.7
24.4
51.0
74.9
68.8
25.9
15.5
37.7
56.8
38.9
35.0
46.3
2.4
3.3
18.6
9.7
8.7
8.9
22.5
27.4
52.2
36.6
23.6
24.4
29.7
12.1
2.9
9.6
13.9
18.5
7.0
6.7
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 4
Table 1. continued.
RA (J2000.0) Dec
20 04 27.42 +34 37 35.3
20 07 22.57 +35 38 32.5
20 08 12.32 +35 59 22.7
20 08 50.48 +35 54 10.6
20 10 36.18 +30 01 27.8
20 11 42.77 +39 39 54.2
20 11 56.67 +37 00 22.9
20 13 16.45 +36 06 30.1
20 16 37.58 +40 18 47.1
20 17 03.42 +40 41 33.9
20 17 13.67 +40 30 31.2
20 17 43.66 +34 19 07.1
20 18 22.11 +39 10 42.7
20 18 23.03 +38 58 15.9
20 18 45.96 +40 55 53.2
20 18 58.45 +40 29 59.9
20 19 05.63 +39 23 51.3
20 19 13.93 +40 54 05.2
20 19 15.88 +40 35 42.3
20 20 02.64 +40 10 52.3
20 20 10.68 +37 09 03.7
20 20 20.60 +39 52 43.8
20 20 37.46 +39 56 44.9
20 20 41.50 +40 48 59.1
20 20 47.07 +38 55 42.2
20 21 25.58 +38 14 04.0
20 22 02.15 +38 50 50.2
20 22 25.44 +38 40 46.1
20 23 52.57 +40 46 05.8
20 24 26.35 +39 02 59.3
20 24 45.41 +39 00 20.9
20 24 46.60 +42 21 42.2
20 25 10.58 +43 52 33.0
20 25 15.11 +39 48 28.1
20 27 17.23 +39 09 42.7
20 29 09.03 +39 31 40.8
20 29 57.91 +39 19 13.5
20 30 52.48 +40 18 16.2
20 31 49.04 +40 15 38.0
20 32 59.66 +45 04 02.6
20 35 45.40 +40 03 32.6
20 36 56.75 +42 15 19.1
20 39 55.96 +49 48 14.4
20 40 31.77 +49 33 03.6
20 40 33.77 +39 48 38.8
20 40 53.55 +39 51 07.2
20 41 27.03 +39 37 30.0
20 43 08.84 +42 46 08.5
20 44 02.83 +39 31 16.3
20 44 33.07 +43 13 21.6
20 45 33.53 +41 07 27.8
20 45 46.40 +45 58 08.4
20 45 55.86 +46 12 01.9
20 46 48.46 +44 11 14.3
20 48 32.87 +44 11 59.7
20 50 21.10 +46 55 44.3
20 50 54.47 +43 46 23.8
20 51 12.11 +47 26 25.5
20 52 15.45 +44 28 10.8
20 52 25.79 +46 18 49.5
20 54 56.93 +44 39 24.5
r
19.36
19.21
18.89
18.67
18.50
15.40
17.61
18.54
16.14
17.55
18.71
18.90
18.80
18.14
16.94
18.54
18.40
16.13
17.74
17.69
18.14
19.50
16.46
16.21
18.30
18.07
17.20
19.37
17.25
16.69
17.52
18.04
15.34
16.55
17.00
19.46
18.62
16.63
17.50
17.93
19.46
17.73
18.79
18.29
18.85
18.34
17.02
16.36
17.77
18.51
18.01
18.30
19.28
18.89
17.89
18.39
16.51
18.64
16.82
18.57
17.85
i
18.10
17.79
17.92
17.65
17.09
14.34
16.59
17.43
15.19
16.13
17.12
17.63
17.58
16.96
15.80
16.96
17.22
14.98
16.44
16.02
17.09
17.77
15.54
15.29
17.02
16.99
16.28
17.82
16.32
15.27
16.00
16.86
13.34
15.48
15.93
17.94
17.20
15.55
16.45
16.91
17.50
16.23
17.77
17.05
17.26
16.69
15.85
15.26
16.36
16.74
16.13
16.49
18.29
16.80
16.39
17.17
15.61
17.50
15.48
17.51
16.21
Hα
17.71
17.57
17.56
17.74
16.86
14.29
16.43
17.54
15.05
16.31
17.59
17.80
17.31
16.39
15.94
17.01
17.05
14.92
16.64
16.53
17.19
18.01
15.36
15.27
17.27
17.01
15.92
17.68
16.21
15.60
16.32
16.86
13.42
15.28
15.59
18.19
17.54
15.36
16.22
16.86
17.86
16.60
17.33
16.93
17.70
17.14
15.61
15.30
16.45
16.84
16.64
17.12
18.32
17.29
16.16
17.37
15.27
17.37
15.47
17.33
16.59
J
16.00
15.83
15.96
16.20
15.37
12.42
14.81
15.41
13.85
14.53
14.70
15.60
15.46
15.07
13.98
14.80
15.11
13.40
14.68
13.62
15.01
15.54
13.98
13.87
14.75
15.07
14.53
15.47
14.88
12.95
13.85
14.79
9.94
13.67
13.81
15.28
15.06
13.78
15.30
14.94
14.93
14.03
15.89
15.16
15.01
14.45
13.90
13.10
14.34
13.52
13.63
14.04
16.43
13.53
14.16
15.06
14.00
15.68
13.20
15.42
14.11
H
14.86
14.69
15.03
14.98
14.63
11.54
13.80
14.33
13.06
13.63
13.56
14.47
14.65
14.06
13.14
13.89
14.17
12.52
13.68
12.64
14.07
14.54
13.20
13.02
13.75
14.17
13.49
14.54
14.06
11.91
12.95
13.90
8.45
12.73
12.85
14.23
14.21
12.91
14.33
13.94
13.96
12.98
14.86
14.19
14.07
13.61
13.00
12.27
13.55
12.49
12.68
13.15
15.39
12.46
13.23
13.95
13.21
14.55
12.21
14.41
13.21
Ks
14.48
14.13
14.55
14.35
14.38
11.15
13.31
13.77
12.81
13.37
12.96
13.94
14.47
13.70
12.93
13.48
13.78
12.17
13.30
12.33
13.60
14.08
12.85
12.71
13.30
13.89
12.98
14.12
13.75
11.38
12.55
13.47
7.73
12.28
12.56
13.93
13.96
12.64
13.90
13.47
13.51
12.56
14.47
13.74
13.85
13.31
12.70
11.90
13.25
11.96
12.26
12.73
15.03
11.95
12.75
13.39
12.97
14.25
11.73
13.91
12.81
d4
29.5
4.7
12.0
12.3
31.9
32.7
19.9
12.5
18.1
9.2
15.1
31.0
8.9
8.0
4.3
14.5
5.9
6.5
11.4
12.7
14.3
10.7
11.3
12.2
13.4
14.0
11.6
12.7
15.0
3.6
4.5
6.2
26.6
28.2
14.2
10.4
18.8
12.8
15.0
19.6
40.8
68.2
20.0
9.4
17.5
18.1
14.1
31.3
29.7
27.6
19.0
12.0
10.7
21.1
21.9
6.2
28.8
15.5
9.6
33.5
8.7
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 5
Table 1. continued.
RA (J2000.0) Dec
20 57 26.70 +43 35 29.6
20 57 55.03 +52 55 54.9
21 00 05.43 +52 17 05.1
21 00 24.07 +52 14 50.8
21 00 58.39 +52 28 56.3
21 01 35.60 +49 52 54.0
21 03 51.54 +48 03 35.1
21 15 51.96 +51 36 20.8
21 16 15.72 +43 36 58.4
21 19 22.95 +46 47 36.0
21 19 39.41 +51 44 12.6
21 20 54.77 +46 52 36.9
21 22 27.33 +52 35 55.7
21 22 40.17 +46 53 55.6
21 26 51.93 +47 34 13.9
21 28 20.10 +55 28 47.9
21 28 56.65 +47 47 42.0
21 35 16.28 +57 28 22.2
21 38 11.37 +58 53 17.2
21 39 35.62 +57 18 21.9
21 39 55.69 +57 16 38.2
21 39 56.13 +57 27 07.9
21 40 20.05 +57 50 44.3
21 40 25.37 +57 34 16.2
21 40 27.32 +58 14 21.3
21 40 37.61 +57 58 33.2
21 41 14.98 +57 38 14.8
21 42 16.79 +57 36 22.0
21 54 08.13 +59 45 35.3
22 06 16.35 +59 02 07.1
22 07 54.48 +59 06 57.1
22 12 14.28 +61 12 46.4
22 14 30.15 +61 32 13.2
22 14 31.30 +61 27 58.7
22 14 51.53 +61 40 12.8
22 15 30.21 +60 46 09.7
22 15 54.21 +52 17 27.5
22 16 00.81 +59 19 51.0
22 16 01.12 +56 14 50.5
22 16 06.52 +52 27 22.5
22 16 24.48 +61 59 19.0
22 25 35.13 +62 58 16.8
22 26 28.63 +61 20 49.0
22 28 43.00 +62 21 33.7
22 45 47.21 +57 50 53.9
22 46 04.51 +60 53 46.0
22 47 27.94 +60 58 53.5
22 47 34.41 +58 07 17.7
22 47 48.64 +63 21 55.1
22 47 59.08 +61 51 26.4
22 50 22.14 +61 53 28.9
22 51 43.33 +62 58 03.0
22 52 01.54 +57 03 22.4
22 53 18.88 +62 29 27.0
22 53 19.03 +62 26 31.7
22 53 45.86 +59 52 16.4
22 53 59.68 +62 37 49.7
22 54 07.90 +62 35 58.6
22 54 58.16 +62 41 32.7
22 55 28.19 +57 08 18.2
22 55 38.34 +63 02 31.6
r
17.22
16.89
15.54
17.97
17.41
17.62
18.95
19.37
19.44
18.29
18.56
16.05
19.21
17.20
16.85
18.16
15.92
17.27
18.54
17.69
18.06
19.42
19.46
18.51
18.22
18.80
17.24
17.13
18.90
16.12
15.46
18.92
18.45
17.73
16.37
18.75
18.12
16.76
18.35
18.86
18.60
17.45
18.68
17.51
15.87
15.75
18.50
18.18
17.34
19.10
17.16
18.59
19.08
17.26
18.29
17.98
16.31
17.69
18.07
18.39
17.47
i
15.78
15.57
14.46
16.46
15.87
16.08
17.05
17.77
17.52
16.34
17.01
14.66
17.67
15.70
15.43
17.41
14.98
15.87
17.02
16.38
16.65
17.74
17.12
16.96
16.78
17.15
15.64
15.46
17.22
14.59
13.88
17.23
16.94
16.04
15.24
17.20
17.32
15.20
16.80
17.92
17.09
16.23
18.13
16.23
14.88
14.60
16.87
17.12
15.91
17.22
16.27
16.85
17.81
15.85
16.79
16.24
15.11
16.22
16.45
17.33
16.19
Hα
15.93
15.64
14.34
16.27
16.27
16.55
17.72
18.27
18.10
16.75
17.22
14.74
17.86
16.01
15.54
17.01
14.50
16.02
17.49
16.33
16.80
17.48
18.13
16.79
16.65
17.56
16.11
15.99
17.50
14.63
14.29
17.58
17.33
16.58
15.38
17.00
17.07
15.47
17.10
17.66
17.51
16.31
16.55
16.44
14.90
14.77
17.24
17.12
16.28
17.33
16.05
17.36
17.92
15.82
17.13
16.81
15.27
16.64
16.84
17.22
16.48
J
13.41
13.62
13.06
13.99
12.33
13.49
15.22
15.67
15.52
13.72
14.78
12.38
15.19
13.77
13.41
16.30
13.29
14.01
14.70
14.50
14.78
15.51
14.49
14.90
14.30
14.90
13.14
13.08
15.13
13.00
12.30
15.10
14.52
13.70
13.39
14.69
15.86
13.21
14.51
16.33
14.61
14.16
14.62
14.21
13.09
12.82
14.39
15.52
13.62
14.51
14.99
14.70
15.80
13.31
14.13
13.12
12.99
14.07
14.12
15.40
14.16
H
12.40
12.60
12.06
13.04
11.08
12.19
14.53
14.76
14.81
12.71
13.90
11.50
13.91
12.86
12.51
15.35
12.56
13.07
13.63
13.58
13.95
14.64
13.58
14.03
13.30
13.99
12.32
12.28
14.31
12.10
11.50
14.28
13.46
12.60
12.48
13.73
14.99
12.41
13.61
15.06
13.53
13.28
13.75
13.31
12.13
11.88
13.42
14.61
12.58
13.51
14.04
13.87
14.79
12.09
13.08
12.01
11.92
13.08
13.05
14.38
13.17
Ks
12.01
12.09
11.63
12.62
10.48
11.71
14.43
14.31
14.51
12.32
13.51
11.09
13.25
12.42
12.15
15.03
12.39
12.67
13.24
13.22
13.73
14.22
13.27
13.61
12.88
13.62
11.92
11.95
14.04
11.74
11.24
13.89
12.93
12.15
12.15
13.33
14.82
12.13
13.25
14.42
13.12
12.97
13.42
12.90
11.68
11.42
12.97
14.44
12.10
13.10
13.72
13.52
14.28
11.47
12.62
11.47
11.38
12.76
12.55
13.88
12.79
d4
16.1
33.7
8.7
8.4
6.5
28.4
19.7
16.8
34.3
2.8
5.7
10.0
23.7
6.8
13.8
20.1
27.9
8.6
35.6
6.4
6.9
1.6
10.2
5.0
3.3
11.7
7.2
11.8
14.0
13.0
8.4
18.6
5.8
2.5
11.0
7.8
8.3
21.6
11.2
5.9
18.1
25.5
24.2
20.4
8.0
13.9
13.1
10.5
29.7
15.7
12.0
13.8
21.4
5.8
7.6
20.7
1.3
2.4
3.6
16.9
6.6
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 6
Table 1. continued.
RA (J2000.0) Dec
22 55 56.25 +62 45 40.5
22 55 59.62 +62 47 44.8
22 56 14.14 +62 43 43.5
22 56 15.81 +62 39 32.8
22 56 30.95 +62 41 38.6
22 57 02.73 +62 29 01.9
22 58 34.40 +61 38 38.5
22 59 15.83 +63 52 24.2
23 00 23.89 +62 48 51.6
23 00 26.92 +62 48 30.9
23 00 29.03 +62 44 14.0
23 00 35.60 +61 17 30.6
23 01 11.35 +62 53 25.3
23 01 44.02 +63 06 16.5
23 02 02.60 +64 03 22.7
23 02 16.34 +56 57 55.6
23 02 18.37 +61 46 19.5
23 02 47.08 +64 48 05.7
23 03 41.77 +61 47 36.1
23 05 01.79 +60 04 54.9
23 05 05.93 +62 08 20.1
23 05 31.15 +60 12 23.9
23 05 46.69 +63 50 17.1
23 12 44.96 +61 46 05.4
23 12 49.78 +59 20 54.5
23 13 34.92 +62 09 44.1
23 14 11.67 +62 18 00.0
23 16 27.57 +63 03 38.1
23 24 50.86 +63 38 15.1
23 27 44.89 +61 09 59.0
23 36 30.38 +63 48 16.4
23 46 28.69 +63 28 02.9
23 46 41.72 +66 53 16.6
23 47 40.63 +63 22 17.5
23 55 30.14 +65 56 57.0
Part B: D-type candidates
00 02 13.37 +64 54 24.6
00 04 09.16 +67 22 37.6
00 04 32.31 +58 08 54.0
00 07 18.66 +65 36 42.1
00 09 36.91 +66 45 45.4
00 10 20.53 +58 37 08.6
00 10 41.20 +66 38 53.2
00 10 55.30 +58 45 53.4
00 11 02.24 +58 42 32.2
00 11 25.46 +58 42 09.6
00 12 59.13 +65 47 00.7
00 14 14.65 +61 00 09.6
00 16 36.19 +63 33 48.6
00 16 43.60 +64 31 38.7
00 18 01.43 +65 48 46.5
00 18 53.83 +62 20 13.3
00 19 03.83 +62 42 25.9
00 21 43.02 +61 47 52.4
00 22 08.28 +61 25 45.3
00 24 57.77 +65 51 34.1
00 26 30.19 +65 51 45.8
00 28 20.89 +65 09 26.3
00 30 13.46 +65 28 12.5
00 35 42.71 +58 59 19.4
00 36 17.42 +66 15 13.3
r
17.25
16.09
18.60
19.17
18.78
19.29
18.74
19.01
17.70
17.66
18.09
18.54
18.90
18.77
18.59
18.95
17.27
18.26
19.11
18.75
18.62
19.10
18.64
14.64
19.01
17.12
18.28
19.02
18.73
18.31
18.56
17.18
17.29
17.16
17.05
i
15.91
14.75
16.94
17.02
17.08
17.45
16.75
17.28
16.24
16.32
16.77
17.31
17.10
17.14
17.05
17.89
15.54
16.91
17.20
17.49
16.93
17.58
17.15
13.94
17.57
15.91
16.65
17.70
17.09
17.21
17.09
15.67
16.01
15.53
15.07
Hα
15.86
15.03
16.98
17.34
17.40
17.31
17.57
17.82
16.43
16.61
16.96
17.37
17.65
17.64
17.34
17.74
16.15
16.65
17.71
17.78
17.39
17.91
17.46
13.66
17.78
15.87
17.08
17.18
17.38
17.26
17.08
15.96
15.56
15.91
15.78
J
13.86
12.65
14.46
14.44
14.36
14.89
14.06
14.68
14.04
14.09
14.53
15.06
14.51
14.59
14.88
16.13
13.21
14.65
14.31
15.56
14.51
15.18
14.80
12.77
15.51
14.13
14.66
15.15
14.79
15.56
14.76
13.59
13.88
13.61
12.65
H
12.80
11.60
13.41
13.53
13.20
13.84
12.88
13.53
13.04
13.21
13.46
13.99
13.58
13.61
13.92
14.71
12.15
13.58
12.85
14.63
13.48
14.08
13.62
12.04
14.70
13.21
13.82
14.03
13.94
14.47
13.88
12.64
12.91
12.70
11.85
Ks
12.34
11.11
12.97
13.07
12.60
13.36
12.31
12.99
12.70
12.80
13.05
13.50
13.19
13.11
13.50
14.06
11.70
13.03
12.07
14.31
13.05
13.64
13.00
11.72
14.43
12.90
13.51
13.63
13.81
14.18
13.44
12.21
12.51
12.32
11.52
d4
2.3
3.4
2.1
2.4
2.1
10.6
20.5
27.3
5.4
5.3
7.1
9.1
6.9
7.8
20.1
19.7
10.1
31.4
4.8
10.4
19.8
6.8
26.5
10.1
21.4
12.8
8.8
22.2
24.1
18.6
30.5
6.4
56.0
7.2
24.4
16.97
16.48
17.36
16.59
19.43
19.36
17.08
17.80
18.46
18.19
18.08
18.39
19.32
17.98
18.62
18.59
19.46
18.37
19.27
19.28
18.77
19.30
18.84
15.82
18.16
16.11
14.92
16.02
15.17
18.02
18.20
15.71
15.98
16.48
16.15
16.82
17.34
18.12
16.85
17.26
17.41
18.37
17.24
18.14
17.70
17.30
17.21
17.42
14.92
16.71
15.62
15.42
15.41
15.30
17.90
17.02
15.64
16.28
17.05
16.83
16.72
17.43
18.33
16.77
17.40
17.42
18.36
17.39
18.19
18.15
17.22
17.77
17.53
14.51
16.60
10.66
12.04
13.63
12.82
15.71
15.74
13.34
13.47
13.86
14.02
15.54
15.35
16.06
14.91
14.88
15.27
16.35
15.13
16.44
14.49
14.95
14.93
14.62
13.73
14.35
9.67
10.86
12.86
11.76
14.53
14.28
12.46
12.42
13.11
13.19
13.74
14.53
14.87
13.98
13.68
14.41
15.53
14.18
15.56
13.33
13.80
14.14
12.88
12.61
13.50
9.05
10.02
12.35
11.11
13.70
13.22
11.91
11.71
12.61
12.76
12.42
13.87
14.08
13.48
12.99
13.91
14.79
13.61
15.02
12.57
12.96
13.72
11.69
11.73
12.80
20.2
47.3
48.2
6.0
23.5
7.3
27.2
3.9
3.3
5.1
11.0
21.2
17.0
17.7
15.6
15.2
12.2
13.5
13.8
19.8
19.2
16.3
4.5
72.2
29.6
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 7
Table 1. continued.
RA (J2000.0) Dec
00 37 56.79 +63 04 59.1
00 38 14.97 +63 05 59.7
00 42 24.91 +66 59 31.9
00 42 32.04 +61 47 57.5
00 42 34.61 +61 17 16.1
00 42 54.48 +61 19 31.2
00 42 55.80 +61 23 47.0
00 43 02.63 +61 09 23.0
00 43 15.16 +61 25 01.4
00 44 17.91 +62 01 18.0
00 44 20.30 +61 58 59.2
00 44 20.78 +61 58 34.1
00 44 46.83 +66 57 06.3
00 54 43.63 +61 09 04.0
00 54 49.44 +63 35 42.6
00 59 30.32 +61 38 54.8
01 03 16.60 +61 37 01.1
01 07 22.27 +59 43 35.2
01 12 20.50 +64 39 17.2
01 19 35.82 +62 55 25.8
01 21 07.17 +61 29 19.5
01 21 09.27 +61 26 52.7
01 21 58.27 +61 30 18.6
01 24 44.28 +61 53 29.9
01 25 44.66 +61 36 11.7
01 37 20.01 +64 59 57.7
01 39 13.79 +62 21 45.3
01 42 03.40 +61 20 52.9
01 43 49.54 +62 29 52.6
01 45 01.50 +64 12 16.5
01 45 50.34 +57 34 03.1
01 45 51.20 +64 16 05.5
02 00 39.48 +60 32 59.1
02 10 08.00 +59 37 32.6
02 16 23.72 +60 16 57.6
02 17 45.54 +66 00 22.3
02 21 03.83 +62 09 58.4
02 21 06.39 +59 01 13.6
02 22 26.45 +61 25 03.3
02 25 25.64 +62 11 57.7
02 26 22.40 +61 33 08.7
02 26 39.54 +62 02 40.0
02 26 53.83 +60 05 43.3
02 27 43.09 +58 11 58.3
02 29 02.78 +61 15 27.7
02 29 14.18 +61 33 25.5
02 29 24.29 +61 13 54.9
02 29 35.91 +61 15 56.8
02 30 24.71 +56 36 57.6
02 31 02.00 +61 07 57.2
02 31 09.66 +60 54 38.9
02 34 10.28 +61 24 40.4
02 34 25.20 +62 21 08.9
02 34 50.40 +62 25 18.5
02 35 03.66 +61 54 52.4
02 35 15.33 +61 48 03.3
02 38 23.48 +61 51 05.2
02 38 28.34 +59 40 01.3
02 39 40.51 +59 04 01.6
02 41 35.93 +57 37 38.0
02 41 47.73 +60 11 09.1
r
17.57
15.84
19.47
19.36
16.76
16.89
18.39
18.55
17.72
18.60
17.10
17.96
18.44
19.38
19.26
15.87
15.30
19.38
17.07
17.18
18.13
17.12
18.22
18.80
18.87
17.47
17.84
18.68
19.33
19.36
16.23
19.03
14.73
17.95
19.28
17.73
18.74
17.03
18.48
18.69
18.35
18.21
18.94
17.87
17.76
17.81
18.29
13.83
17.08
17.84
18.71
13.64
18.27
18.96
16.78
16.75
18.09
18.85
17.54
18.82
16.13
i
16.63
14.85
18.13
17.29
15.60
15.46
16.95
16.89
16.27
16.63
15.56
16.27
17.26
17.65
17.98
14.71
14.33
18.16
15.63
15.91
16.78
16.18
16.77
17.35
18.20
16.01
16.48
17.54
17.97
18.28
15.59
17.86
14.12
16.77
17.98
16.54
17.45
16.02
16.95
17.33
17.05
17.00
17.17
16.93
16.46
16.52
16.83
12.98
16.25
16.45
17.30
12.97
17.06
17.68
15.83
15.67
17.06
17.71
16.23
17.88
14.79
Hα
15.48
14.59
18.31
17.92
15.78
15.33
16.91
17.10
16.61
16.93
15.98
16.66
17.21
18.15
17.90
14.90
14.22
18.29
15.91
16.01
16.73
16.14
16.84
17.31
16.86
15.51
16.54
17.53
18.02
17.99
15.29
17.34
12.79
16.93
18.05
16.44
17.65
16.08
16.98
17.63
17.18
17.07
17.69
16.95
16.69
16.83
17.13
12.76
16.18
16.76
17.62
12.46
17.23
17.64
15.89
15.63
17.17
17.76
16.38
17.68
14.99
J
14.56
12.50
16.29
14.69
13.69
12.53
14.32
14.32
14.29
13.83
13.58
13.77
15.35
14.30
15.34
12.82
12.18
16.48
13.30
13.64
14.02
14.26
14.50
14.60
15.48
13.62
13.79
15.29
15.44
15.91
12.49
15.65
12.45
14.57
15.56
14.37
15.36
13.77
14.17
15.17
14.64
14.90
14.78
15.17
14.24
14.37
14.41
11.14
14.68
13.88
14.14
11.44
14.88
15.48
14.06
13.54
15.26
15.89
13.86
16.42
12.53
H
13.59
11.48
15.12
13.56
12.74
11.15
13.24
13.31
13.27
13.08
12.69
12.84
14.48
13.15
14.13
11.93
11.26
15.68
12.17
12.46
13.03
13.15
13.51
13.45
13.22
12.69
12.48
14.14
14.14
14.94
10.92
14.50
11.26
13.35
14.47
13.17
14.32
12.46
12.85
14.01
13.49
13.85
13.91
14.30
13.18
13.28
13.21
9.91
13.90
12.67
13.03
10.41
13.70
14.60
13.17
12.51
14.33
14.96
12.69
15.14
11.83
Ks
12.97
10.64
14.24
12.86
12.23
9.98
12.54
12.73
12.70
12.61
12.18
12.27
13.67
12.47
13.03
11.33
10.70
14.92
11.48
11.55
12.47
12.51
12.85
12.74
11.49
12.08
11.51
13.41
13.26
14.30
9.72
13.28
9.88
12.53
13.65
12.31
13.66
11.32
11.99
13.25
12.73
13.20
13.41
13.74
12.57
12.59
12.48
8.94
13.42
11.81
12.33
9.51
12.83
14.00
12.57
11.77
13.86
14.23
11.91
13.30
11.26
d4
20.2
20.3
37.6
9.0
4.4
4.3
5.3
7.2
6.8
5.4
5.6
5.9
40.9
33.5
31.7
41.4
43.9
45.8
16.5
36.0
8.6
8.8
8.0
17.7
21.5
28.1
30.5
30.0
17.7
13.6
39.8
17.5
33.6
27.4
30.6
33.3
26.5
41.0
31.8
17.1
17.2
11.8
10.4
36.3
10.3
9.1
8.7
9.2
63.4
10.2
9.5
9.3
19.0
20.1
12.2
9.1
12.0
18.2
22.1
7.0
19.3
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 8
Table 1. continued.
RA (J2000.0) Dec
02 43 26.34 +59 06 31.1
02 44 39.54 +60 59 54.8
02 44 42.09 +60 34 27.5
02 45 07.00 +61 07 44.0
02 47 48.61 +60 57 50.4
02 48 34.20 +60 27 55.5
02 49 49.77 +60 17 15.2
02 49 53.35 +60 13 28.3
02 51 51.96 +60 13 09.3
02 51 58.30 +60 23 59.2
02 52 07.87 +60 14 55.6
02 53 38.45 +60 41 16.0
02 53 56.29 +60 39 20.7
02 54 00.78 +60 36 39.5
02 54 06.19 +60 38 33.5
02 54 17.67 +60 38 14.7
02 54 56.86 +60 38 13.7
02 55 45.29 +59 04 38.2
02 56 02.38 +61 11 59.9
02 57 20.41 +60 44 46.6
02 57 21.57 +60 53 09.5
02 57 57.37 +60 20 40.7
02 58 24.52 +60 34 16.4
02 58 51.22 +60 39 54.5
02 59 02.08 +60 36 24.4
02 59 25.87 +60 28 59.4
02 59 40.84 +60 34 53.6
02 59 42.81 +60 28 21.2
03 01 05.20 +60 31 55.4
03 01 34.36 +60 30 08.6
03 04 11.04 +60 55 04.1
03 05 55.54 +60 37 09.4
03 06 14.52 +58 39 35.0
03 09 02.19 +58 29 52.3
03 10 46.27 +59 30 03.6
03 14 05.39 +58 44 53.4
03 16 53.16 +60 03 05.5
03 16 53.27 +60 16 59.9
03 16 56.98 +59 57 39.3
03 17 41.86 +53 08 50.2
03 18 07.44 +59 03 39.7
03 19 12.06 +59 40 09.5
03 20 36.40 +60 18 18.3
03 20 39.49 +56 23 58.2
03 25 08.89 +60 56 54.6
03 25 36.55 +56 05 33.2
03 26 38.60 +58 51 25.1
03 27 55.71 +58 18 06.0
03 28 35.36 +58 56 56.0
03 28 57.92 +58 40 50.3
03 30 13.60 +58 04 23.6
03 31 32.99 +60 35 55.9
03 31 55.48 +58 22 32.7
03 32 02.36 +59 32 00.7
03 35 40.02 +57 58 35.7
03 45 13.72 +54 35 25.9
03 46 09.84 +54 55 50.8
03 50 01.78 +53 07 56.2
03 50 46.67 +54 01 09.3
03 55 30.05 +53 45 42.0
03 56 08.31 +53 45 26.0
r
16.64
16.24
19.05
19.01
14.02
18.64
18.39
16.78
18.73
18.49
17.41
18.68
18.16
19.43
17.79
18.52
19.45
17.25
17.91
19.32
19.02
17.55
18.51
18.68
17.60
19.19
18.37
18.27
15.85
19.30
18.89
18.79
19.26
18.42
15.08
19.00
19.43
18.05
18.97
18.15
17.75
18.78
15.85
14.68
19.28
16.63
18.77
18.01
18.48
19.35
18.60
16.71
18.24
17.75
18.37
16.93
17.59
18.93
16.87
18.47
15.78
i
15.57
15.22
17.71
17.60
13.49
17.41
17.13
15.77
17.53
17.58
16.35
17.64
17.11
18.14
16.71
17.39
18.23
16.50
16.58
17.91
17.62
16.50
17.36
17.40
16.60
17.96
17.23
17.27
14.77
17.60
17.61
17.41
17.62
17.30
14.51
17.66
17.97
16.61
17.51
17.04
16.34
17.14
14.52
13.40
18.76
15.30
17.04
16.81
17.23
17.64
16.98
15.94
16.64
16.33
16.76
15.49
16.18
17.36
15.34
16.49
14.18
Hα
15.39
15.11
17.95
17.69
13.14
17.57
16.96
15.51
17.44
17.29
16.48
17.40
16.79
18.41
16.85
17.27
18.37
16.28
16.85
17.95
17.66
16.39
17.25
17.49
16.23
18.20
16.99
17.07
14.91
17.99
17.50
17.40
17.67
17.18
14.29
17.61
18.06
16.77
17.12
17.11
16.52
17.59
14.85
13.07
18.26
15.64
17.20
16.96
16.84
17.99
17.35
15.54
16.96
16.50
17.22
15.83
16.50
17.76
15.67
17.28
14.73
J
13.68
13.17
15.67
15.52
12.04
15.24
15.03
13.72
15.33
15.39
14.37
15.36
15.04
16.05
14.89
15.61
15.86
14.43
13.90
15.58
14.07
14.42
15.41
15.22
14.70
15.58
15.07
15.59
12.85
14.78
15.16
15.00
15.19
14.62
12.82
15.70
15.55
13.34
15.14
15.04
14.38
15.41
12.10
10.95
16.87
13.21
14.22
14.38
14.59
14.99
14.17
13.98
13.95
13.76
14.35
13.25
14.10
15.07
13.14
12.55
11.62
H
12.73
12.10
14.44
14.35
10.94
14.16
13.81
12.73
14.31
14.36
13.35
14.45
14.09
15.24
13.73
14.61
15.06
12.91
12.62
14.70
12.81
13.57
14.62
14.18
13.73
14.45
13.99
14.65
11.90
13.43
13.90
13.81
14.20
13.51
11.75
14.65
14.34
12.12
13.80
14.04
13.43
14.29
10.81
9.57
15.50
12.46
13.00
13.41
13.57
14.01
12.92
13.20
12.81
12.66
12.94
12.47
13.33
14.12
11.90
10.92
10.73
Ks
12.20
11.25
13.78
13.63
9.96
13.30
13.04
11.95
13.71
13.57
12.57
13.87
13.39
14.82
12.85
13.88
14.54
11.65
11.62
14.19
11.79
13.02
14.13
13.49
13.07
13.83
13.29
13.95
11.29
12.56
13.06
13.02
13.61
12.73
10.65
14.02
13.66
11.25
12.88
13.40
12.62
13.53
9.86
8.22
14.44
11.88
12.31
12.90
13.02
13.36
12.12
12.76
12.21
12.06
11.93
11.84
12.76
13.41
11.09
9.65
10.17
d4
23.7
9.1
9.0
10.5
23.8
17.6
10.7
11.2
4.8
4.8
4.2
3.9
2.1
2.0
1.6
1.8
2.2
30.8
12.7
6.7
8.1
8.4
4.3
5.1
3.9
1.8
1.7
2.0
3.0
3.1
21.4
22.9
21.5
26.5
29.5
26.5
10.9
12.8
13.3
42.0
22.0
18.4
3.5
35.3
26.5
35.6
10.6
22.7
12.9
19.8
23.1
23.0
19.6
34.7
25.4
25.9
25.9
40.1
21.3
29.2
28.9
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 9
Table 1. continued.
RA (J2000.0) Dec
03 56 19.88 +52 29 44.0
03 56 34.20 +51 48 33.2
03 57 00.59 +51 47 34.8
03 57 07.52 +57 41 42.7
03 57 19.39 +57 07 43.1
03 58 23.95 +52 23 12.6
03 58 41.02 +51 37 23.9
03 59 23.18 +51 42 50.8
04 00 06.20 +51 39 02.3
04 00 56.06 +58 45 29.0
04 02 20.91 +52 51 01.9
04 04 50.08 +54 27 44.8
04 08 10.62 +52 42 58.6
04 09 30.70 +52 44 50.6
04 09 36.51 +49 03 06.8
04 10 11.85 +50 59 54.6
04 18 47.61 +52 42 56.3
04 22 40.39 +46 17 46.3
04 22 56.11 +53 47 09.4
04 23 03.57 +43 26 51.0
04 24 04.10 +44 53 46.7
04 25 04.65 +50 49 57.7
04 27 54.38 +48 10 08.6
04 29 14.20 +45 24 34.8
04 29 26.85 +45 16 10.2
04 30 22.43 +53 48 53.4
04 32 28.30 +46 20 17.1
04 32 36.68 +42 41 21.1
04 33 47.04 +44 31 32.7
04 41 12.44 +47 16 52.3
04 43 38.64 +41 09 41.5
04 45 39.97 +42 02 29.9
04 45 42.71 +42 02 13.8
04 54 32.84 +43 21 23.8
04 56 25.15 +43 49 31.8
04 57 17.54 +40 21 21.7
05 01 24.25 +46 48 47.7
05 02 19.46 +48 03 37.6
05 07 47.35 +40 23 55.3
05 08 00.97 +42 42 12.5
05 08 05.09 +40 24 40.3
05 08 10.23 +40 53 51.8
05 13 48.76 +32 42 06.7
05 22 43.78 +33 25 25.8
05 22 54.80 +33 27 18.7
05 24 43.05 +35 01 23.3
05 25 14.61 +43 15 49.4
05 25 27.71 +43 14 07.1
05 26 10.73 +33 37 50.8
05 27 07.61 +34 57 24.8
05 27 07.83 +34 57 27.6
05 27 32.45 +35 02 40.7
05 27 42.63 +34 41 52.9
05 27 46.99 +34 44 01.1
05 28 08.59 +34 25 38.4
05 28 29.01 +35 01 38.8
05 28 29.06 +31 03 24.4
05 28 32.58 +34 59 22.6
05 28 57.93 +35 09 37.0
05 30 29.55 +33 32 20.8
05 31 13.16 +38 20 06.6
r
19.41
17.88
16.33
19.25
18.91
18.96
19.30
18.62
17.48
19.09
18.83
18.43
18.07
19.47
19.05
16.82
19.34
18.66
19.30
18.37
19.43
18.10
19.34
17.03
17.23
18.53
19.33
18.45
18.45
18.29
15.02
19.31
18.67
17.72
18.13
16.26
15.07
18.68
18.57
17.57
18.25
19.17
18.82
16.51
19.10
18.42
17.62
18.14
18.24
18.66
18.38
17.22
18.76
18.77
16.01
18.92
17.91
18.98
17.66
18.48
16.53
i
18.00
16.37
15.40
18.33
17.82
17.77
18.00
17.23
16.47
18.04
17.84
17.23
17.01
18.26
17.97
14.71
18.19
17.51
18.20
17.68
18.16
16.61
18.09
16.05
15.94
17.22
17.79
17.27
17.32
17.05
14.02
18.18
17.20
16.54
17.13
15.14
13.80
17.63
17.69
16.58
17.20
18.30
17.73
15.09
18.22
17.28
16.86
17.28
17.18
17.66
17.41
16.36
17.56
17.83
15.25
17.82
16.71
17.90
16.82
17.12
15.68
Hα
18.19
16.39
14.79
17.47
17.92
17.05
18.01
17.49
16.29
17.48
17.48
17.30
16.67
18.43
18.07
15.38
18.07
17.33
18.06
17.25
18.04
16.85
17.80
15.82
15.74
16.70
17.68
17.19
17.32
16.88
13.83
18.27
17.26
16.68
16.29
15.01
14.06
17.35
17.12
16.25
17.12
17.17
17.50
15.24
17.78
17.13
16.65
16.94
17.30
17.24
17.27
16.30
17.07
17.64
14.95
17.36
16.96
17.96
16.70
17.39
14.94
J
15.43
13.98
13.29
16.00
15.72
15.74
15.85
15.10
14.16
15.93
15.81
14.95
14.95
15.86
15.74
10.92
15.96
15.24
16.27
16.34
16.22
13.82
15.51
14.47
14.04
14.98
15.48
15.02
15.38
14.86
12.25
16.33
14.68
15.06
15.25
12.82
12.30
16.12
15.43
14.88
15.09
16.46
15.27
12.38
16.59
15.11
15.21
15.17
15.22
15.33
15.69
14.56
15.67
15.95
13.51
15.66
14.60
16.15
15.19
15.44
12.54
H
14.61
12.84
12.41
15.12
14.82
14.83
14.71
14.18
13.23
14.85
14.80
13.82
13.86
14.96
14.65
8.90
14.83
14.15
15.57
15.62
15.16
12.99
13.54
13.46
12.62
13.92
14.63
13.77
14.30
13.80
11.19
15.45
13.46
14.13
14.08
11.77
11.22
15.32
14.45
13.90
14.00
15.60
14.21
10.77
15.53
14.10
14.30
14.20
14.21
14.11
14.75
13.54
14.77
15.24
12.50
14.85
13.48
15.12
14.31
14.35
11.74
Ks
14.09
12.18
11.91
14.48
14.15
14.30
13.80
13.63
12.63
14.00
14.21
12.79
13.18
14.50
13.96
7.12
13.98
13.42
14.75
15.06
14.44
12.49
11.94
12.68
11.44
13.10
14.19
12.82
13.53
13.06
10.17
14.84
12.53
13.51
13.04
11.10
9.99
14.44
13.62
13.24
13.28
15.07
13.43
9.42
14.76
13.50
13.51
13.43
13.62
13.13
14.27
12.90
14.21
14.85
11.83
14.31
12.87
14.50
13.85
13.74
11.14
d4
14.9
15.6
13.6
24.5
5.1
13.2
9.6
8.0
9.8
47.6
23.3
27.6
16.6
18.8
68.2
40.8
29.5
47.5
24.3
53.9
37.6
43.3
38.1
8.7
12.2
47.8
44.6
32.6
26.0
26.2
42.7
3.0
3.2
42.1
36.8
30.7
36.6
55.4
29.0
25.6
28.7
36.9
45.0
4.2
3.3
17.2
60.6
59.1
32.3
7.2
7.2
9.4
2.9
2.7
1.8
6.5
36.1
7.4
8.3
9.6
31.0
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 10
Table 1. continued.
RA (J2000.0) Dec
05 32 04.48 +30 17 31.3
05 32 09.27 +30 18 53.0
05 33 09.32 +32 50 30.1
05 33 50.71 +30 42 54.0
05 34 23.83 +25 39 10.5
05 34 40.77 +25 42 38.2
05 35 17.98 +27 47 58.1
05 35 23.89 +32 17 21.7
05 35 38.79 +32 21 15.2
05 35 44.51 +36 49 40.1
05 36 11.80 +27 34 36.0
05 36 31.98 +31 49 39.6
05 37 06.57 +27 47 24.2
05 37 12.44 +27 48 04.0
05 37 13.51 +26 56 59.2
05 37 28.60 +32 00 01.5
05 37 51.20 +27 03 46.0
05 38 17.88 +31 39 34.8
05 38 21.92 +27 28 32.4
05 38 23.09 +23 02 18.3
05 39 06.05 +30 49 33.0
05 39 17.83 +27 27 47.0
05 39 23.87 +27 26 50.4
05 39 27.29 +30 51 51.0
05 39 55.76 +33 24 12.8
05 40 40.97 +35 27 24.4
05 40 54.32 +35 25 54.9
05 41 32.75 +26 55 13.6
05 41 46.63 +27 27 48.0
05 42 13.34 +34 12 00.6
05 42 40.94 +33 45 15.2
05 42 52.04 +31 00 14.2
05 44 24.19 +31 20 31.4
05 46 21.54 +26 27 24.0
05 46 35.52 +26 19 09.8
05 47 03.77 +21 00 34.8
05 47 13.95 +22 11 00.5
05 47 45.79 +22 48 29.1
05 47 53.19 +30 36 50.4
05 48 07.74 +22 56 53.6
05 49 03.72 +22 27 08.7
05 49 12.30 +33 07 24.5
05 49 14.20 +27 00 21.7
05 49 34.57 +23 19 31.7
05 49 42.86 +28 23 15.6
05 49 45.05 +27 04 16.1
05 49 50.54 +27 07 01.5
05 50 28.14 +23 59 51.1
05 50 31.16 +31 27 46.0
05 50 38.56 +27 03 15.8
05 50 50.63 +24 06 11.9
05 51 12.18 +25 46 03.3
05 51 16.76 +25 42 13.9
05 52 01.57 +26 57 33.7
05 52 45.11 +17 11 19.1
05 52 54.08 +17 14 24.7
05 55 32.35 +27 44 51.4
05 57 24.37 +20 08 00.5
05 58 32.17 +19 57 12.6
05 59 20.12 +24 33 07.9
05 59 23.17 +16 56 33.5
r
18.90
18.68
17.72
17.62
18.53
17.48
18.12
17.93
18.82
19.08
15.53
18.37
19.40
16.42
18.66
17.70
18.40
16.23
18.24
17.38
17.92
18.50
18.94
19.39
16.30
18.60
16.40
17.33
18.37
17.88
18.91
18.19
16.36
15.60
17.68
18.11
18.88
18.61
18.53
18.65
18.10
17.99
19.20
18.08
18.42
16.97
16.42
19.45
17.98
19.12
17.65
18.51
17.99
19.12
16.40
16.47
17.25
19.07
19.09
17.46
19.41
i
17.63
17.37
16.67
16.32
17.04
16.28
17.04
16.77
17.66
17.78
14.49
16.94
17.85
15.45
17.47
16.70
17.38
15.19
17.14
16.51
16.90
17.26
17.64
17.99
15.27
17.19
15.59
15.69
17.17
16.67
17.90
17.07
15.21
14.70
16.63
16.54
18.09
17.08
17.44
17.12
17.05
16.99
17.37
16.90
17.26
15.90
15.38
18.20
17.17
17.47
16.76
16.95
16.64
17.76
15.27
15.54
16.31
17.79
17.65
16.56
18.19
Hα
17.65
17.40
16.22
16.50
17.05
15.63
16.64
16.97
17.02
18.00
14.28
17.29
18.04
15.23
17.65
16.32
16.98
14.88
17.09
16.22
16.43
17.00
17.43
17.53
15.32
17.21
15.03
16.11
16.75
16.93
17.47
17.13
15.38
14.31
16.73
16.75
17.81
17.00
16.93
17.40
16.91
16.91
17.84
16.48
17.25
15.79
15.48
18.34
16.98
17.80
16.59
17.05
16.66
17.91
15.16
14.58
15.89
18.08
17.88
16.19
18.26
J
15.34
15.20
14.93
14.10
14.88
14.09
15.25
15.01
15.81
15.64
13.46
14.44
15.41
13.43
15.88
14.99
15.20
13.46
15.00
14.13
15.22
14.80
15.43
15.47
13.20
14.72
14.05
13.38
14.99
14.55
15.98
14.90
13.33
12.68
14.61
11.56
16.45
14.13
15.31
14.69
14.87
14.50
13.81
14.80
15.37
13.67
13.90
15.86
15.57
14.76
14.65
14.17
13.78
15.23
13.78
13.86
14.77
15.68
15.49
15.20
15.84
H
14.28
14.25
13.98
12.88
13.93
12.12
14.27
14.09
15.00
14.74
12.31
13.16
13.87
12.38
14.75
13.82
14.18
12.63
14.03
13.05
14.36
13.73
14.15
14.39
12.00
13.35
12.94
12.47
14.03
13.52
15.03
13.91
12.24
11.68
13.60
10.74
15.56
12.97
14.37
13.39
13.63
13.19
12.55
13.73
14.38
12.60
13.00
14.75
14.61
13.24
13.60
12.77
12.45
14.00
12.95
13.03
13.86
14.66
14.53
14.12
14.87
Ks
13.64
13.37
13.47
12.16
13.38
10.58
13.65
13.60
14.56
14.12
11.32
12.44
12.81
11.66
13.70
13.00
13.49
11.71
13.33
12.29
13.72
13.04
13.26
13.70
11.00
12.47
12.18
12.00
13.46
12.87
14.27
13.28
11.61
10.95
12.96
10.28
15.09
12.18
13.76
12.66
12.90
12.16
11.59
13.14
13.68
11.83
12.36
14.12
13.99
12.27
12.85
11.75
11.51
13.32
12.51
12.50
13.31
14.07
13.99
13.25
14.02
d4
8.0
8.3
25.0
32.4
8.6
11.3
13.2
11.2
10.1
30.6
12.5
4.3
6.5
6.7
16.2
13.0
12.0
22.5
11.0
42.9
18.9
11.7
12.8
18.2
46.8
20.1
21.1
35.7
22.8
41.3
34.8
27.5
38.8
24.1
26.4
40.2
29.4
23.2
32.1
24.8
29.6
17.6
13.3
38.0
18.2
8.7
8.6
21.7
31.9
15.4
19.7
29.5
29.4
27.6
51.8
51.9
44.6
14.1
16.2
34.8
36.0
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 11
Table 1. continued.
RA (J2000.0) Dec
06 00 04.54 +16 51 26.0
06 00 19.28 +20 11 59.2
06 00 35.17 +31 29 55.8
06 02 11.11 +26 22 32.1
06 02 36.34 +30 57 44.2
06 02 40.22 +31 21 40.2
06 05 15.15 +20 40 36.7
06 06 24.06 +23 32 35.1
06 06 33.01 +30 06 40.5
06 06 44.63 +19 50 38.6
06 07 15.86 +19 30 00.1
06 08 30.13 +16 27 39.6
06 08 52.63 +20 37 28.3
06 09 23.62 +21 02 35.8
06 09 26.79 +24 55 19.9
06 09 29.56 +20 41 26.3
06 09 35.23 +12 40 22.8
06 10 08.00 +12 17 34.8
06 10 24.41 +12 46 47.6
06 10 45.52 +19 48 17.0
06 12 49.24 +18 03 52.6
06 12 58.84 +15 18 35.4
06 13 02.76 +15 35 27.3
06 13 12.70 +15 20 36.7
06 13 14.30 +17 53 43.9
06 13 17.53 +15 19 57.8
06 13 22.66 +21 57 46.3
06 13 28.57 +16 05 56.9
06 14 17.27 +22 54 18.6
06 14 29.10 +20 09 56.5
06 15 22.28 +18 56 55.2
06 16 38.92 +20 01 51.6
06 17 19.51 +23 36 06.8
06 17 19.67 +24 51 25.0
06 17 29.17 +22 21 52.4
06 17 58.15 +24 11 49.2
06 18 04.17 +18 30 10.3
06 18 05.61 +17 40 43.0
06 18 06.94 +13 02 03.7
06 20 21.71 +11 07 10.2
06 20 47.11 +10 57 25.7
06 22 06.60 +22 34 29.5
06 23 11.57 +23 42 51.3
06 23 35.18 +23 10 41.0
06 23 41.27 +22 58 05.9
06 23 52.13 +14 26 19.2
06 24 21.99 +14 33 15.3
06 24 38.78 +09 18 25.9
06 28 42.43 +09 32 09.2
06 30 37.20 +04 54 02.7
06 30 39.33 +05 21 42.1
06 30 48.17 +09 46 04.2
06 30 56.81 +04 38 34.1
06 31 01.43 +10 41 02.0
06 31 02.58 +09 59 20.6
06 31 05.43 +10 01 26.3
06 31 09.62 +10 25 57.5
06 31 10.28 +09 59 17.2
06 31 13.16 +10 26 57.2
06 31 13.55 +10 27 00.0
06 31 16.26 +05 06 51.1
r
18.98
18.16
17.72
18.66
19.13
19.44
17.82
17.77
18.28
17.94
15.05
15.92
17.14
17.74
16.48
18.80
17.97
18.88
15.88
17.83
19.26
18.12
17.80
14.79
17.76
19.48
18.13
16.10
18.60
18.49
18.66
19.37
17.50
18.05
17.26
19.16
18.50
19.12
17.82
18.62
19.17
17.99
18.85
19.35
18.71
17.36
18.31
18.14
15.26
16.70
17.11
16.62
16.82
18.30
17.82
18.68
17.35
14.44
19.38
16.87
17.18
i
18.18
17.09
16.34
18.16
18.14
18.51
16.48
16.69
17.24
16.91
14.20
15.13
16.25
16.29
15.93
17.67
16.66
17.75
15.05
16.61
17.93
16.94
16.66
14.01
16.79
18.34
17.26
14.95
18.11
17.26
17.64
18.14
16.34
17.01
16.36
18.12
17.34
18.01
16.87
17.45
18.12
16.83
17.59
18.05
17.41
16.35
17.17
17.15
14.22
15.51
15.89
15.45
15.83
16.46
16.45
17.14
15.43
13.51
16.94
15.31
16.26
Hα
17.42
16.66
16.59
17.89
17.88
18.49
16.43
16.61
17.05
16.79
14.17
15.04
16.25
16.60
15.42
17.34
16.95
17.42
14.22
16.73
17.98
16.95
16.70
13.87
16.61
18.12
17.23
14.99
16.70
17.32
17.55
17.99
16.35
16.71
16.32
17.90
17.15
17.76
16.26
17.44
17.65
16.65
17.63
17.92
17.62
16.15
17.29
16.72
14.28
15.59
15.96
15.04
15.65
17.11
16.34
17.38
15.73
13.51
17.97
15.14
16.25
J
16.69
15.26
14.50
16.76
16.38
16.90
14.77
14.70
15.75
15.19
13.45
13.61
14.42
13.17
12.26
15.59
13.97
15.35
13.30
15.05
15.12
15.05
14.68
12.44
14.95
16.07
15.11
13.11
14.55
15.61
15.60
15.80
14.12
15.42
14.85
16.27
14.96
15.96
15.39
16.22
16.26
15.08
15.36
14.86
15.08
14.60
15.16
15.34
12.68
12.93
13.70
13.53
13.83
13.74
15.66
14.88
12.85
11.60
14.32
12.93
14.67
H
15.69
14.29
13.04
15.54
15.61
15.95
13.21
13.49
14.58
14.21
12.37
12.59
13.51
11.84
11.20
14.76
12.41
14.03
12.28
13.89
13.85
13.80
13.69
11.44
13.95
15.29
14.17
12.05
13.29
14.43
14.76
14.23
12.72
14.52
13.85
15.32
14.11
14.89
14.41
15.07
15.04
13.80
14.28
13.76
14.12
13.59
14.14
14.53
11.84
11.66
12.66
12.62
12.80
12.59
14.22
14.14
11.88
10.76
13.63
11.90
13.82
Ks
14.71
13.73
12.15
14.22
15.20
15.34
11.22
12.65
13.92
13.65
11.64
11.96
13.04
10.91
10.24
14.27
11.10
13.08
11.51
13.21
12.91
12.93
13.12
10.57
13.34
14.29
13.52
11.47
12.28
13.68
14.07
13.25
11.78
13.73
13.31
14.47
13.50
14.10
13.80
13.99
14.15
12.94
13.37
13.02
13.42
12.92
13.45
13.79
11.35
10.71
12.08
12.09
12.08
11.95
13.43
13.73
11.27
10.25
13.21
11.25
13.37
d4
28.8
13.8
29.3
50.3
23.4
21.2
56.1
64.4
34.7
40.7
32.9
45.6
24.3
30.2
39.3
24.4
15.6
22.7
18.1
31.9
33.5
5.0
14.6
4.2
27.4
4.6
28.0
29.2
22.4
18.1
30.2
29.9
34.9
43.3
30.6
34.0
38.8
36.1
57.7
40.1
39.5
10.2
30.6
15.2
11.3
13.1
12.1
10.6
36.6
14.0
20.3
15.9
15.3
14.2
7.9
8.2
1.7
7.8
1.3
1.3
9.3
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 12
Table 1. continued.
RA (J2000.0) Dec
06 31 19.11 +10 22 46.5
06 31 19.66 +04 52 41.9
06 31 27.85 +04 50 02.9
06 31 29.67 +10 23 23.1
06 31 30.96 +05 06 58.5
06 31 46.86 +10 07 48.5
06 31 47.05 +04 48 11.0
06 31 48.05 +04 50 48.3
06 32 06.21 +10 36 27.7
06 32 14.59 +10 07 37.1
06 32 21.34 +04 46 19.2
06 32 31.50 +04 54 53.4
06 32 43.35 +05 02 20.6
06 32 46.98 +10 16 38.1
06 33 22.32 +04 36 38.2
06 33 32.26 +04 57 39.5
06 33 32.39 +04 57 49.2
06 34 16.90 +04 24 19.2
06 36 25.88 +02 16 16.2
06 36 42.85 +05 37 36.8
06 36 54.07 +04 00 46.8
06 38 49.77 +06 23 35.4
06 39 34.25 +06 21 16.9
06 42 22.19 -02 26 28.6
06 58 50.75 -01 40 43.3
18 28 15.04 -00 02 59.0
18 28 50.22 +00 09 49.6
18 37 53.26 +00 18 49.2
18 38 14.63 -01 22 13.8
18 40 28.54 +00 07 16.5
18 42 22.67 +02 58 07.0
18 44 31.46 -00 16 52.4
18 46 27.71 +00 28 17.8
18 46 35.85 +00 55 21.4
18 50 05.71 -00 40 41.2
18 51 38.28 -02 14 26.0
18 51 56.32 +06 19 46.1
18 52 31.44 +02 15 25.3
18 53 49.55 +05 23 53.7
18 54 03.70 +03 55 26.7
18 54 24.82 +04 19 05.0
18 55 06.04 +00 54 26.9
18 55 26.72 -04 05 37.5
18 57 07.14 +02 22 26.0
19 00 15.86 +00 05 17.3
19 00 21.58 +05 20 01.1
19 02 29.97 -02 27 57.0
19 03 46.84 +16 26 16.9
19 08 57.31 +05 36 20.6
19 10 17.43 +06 52 58.1
19 12 33.23 +11 46 31.2
19 17 01.33 +15 59 47.8
19 19 30.75 +13 32 42.5
19 20 33.79 +23 10 40.3
19 22 49.80 +14 22 36.3
19 22 57.72 +11 38 54.8
19 24 00.05 +23 02 53.1
19 25 04.10 +22 44 38.5
19 25 14.31 +22 41 44.1
19 25 17.16 +22 33 55.9
19 25 38.41 +22 34 14.6
r
19.10
18.06
16.44
17.18
15.17
17.09
18.30
17.58
14.80
17.50
17.41
18.83
17.34
17.78
16.70
18.24
16.32
17.13
16.93
17.70
18.18
17.85
18.80
19.22
18.93
18.35
17.86
19.06
17.30
19.27
16.03
17.21
18.94
14.86
16.95
15.14
17.81
18.91
18.48
19.30
18.29
19.02
19.30
18.79
14.94
17.90
16.13
13.98
16.89
15.81
18.60
17.70
19.48
16.89
16.96
18.63
15.79
19.04
16.84
16.14
14.68
i
17.59
16.91
15.62
15.86
14.37
15.40
17.17
16.28
13.30
16.33
16.29
17.74
16.49
16.49
15.76
17.04
15.34
15.93
15.79
16.78
16.86
16.95
18.31
17.77
17.64
16.26
15.78
16.48
15.30
17.40
15.04
15.76
17.23
13.69
15.59
13.54
16.00
16.78
17.08
17.62
16.46
17.15
16.76
17.19
13.96
16.73
16.30
11.95
15.82
13.89
16.86
16.20
18.05
15.39
15.32
17.28
14.68
17.17
15.39
14.69
13.70
Hα
17.81
16.77
15.26
15.78
14.21
15.96
17.07
16.48
13.73
16.03
16.44
16.71
16.02
16.12
15.56
16.73
15.05
15.97
15.74
16.39
17.14
16.91
17.48
17.94
17.77
17.14
16.43
17.52
15.75
18.14
15.08
16.00
17.57
13.70
15.72
13.88
16.28
17.45
16.70
18.05
17.10
17.63
18.00
17.43
13.99
15.95
13.19
12.08
15.95
14.10
17.09
16.34
18.29
15.85
15.62
17.50
14.56
17.67
15.69
14.88
13.65
J
14.37
15.09
13.79
13.39
12.88
13.54
15.24
14.15
11.01
13.82
14.27
15.80
14.77
12.77
14.09
15.12
13.57
13.78
13.91
14.85
14.79
15.35
16.77
15.85
15.67
13.69
13.01
13.05
12.16
14.57
13.32
12.54
14.06
11.73
13.00
10.62
13.27
13.78
14.34
14.28
13.13
15.36
14.23
14.30
12.18
13.73
13.42
8.73
12.83
10.42
13.99
13.43
15.91
13.43
12.61
14.28
12.82
14.82
13.33
12.77
11.79
H
12.81
14.13
12.80
12.32
12.08
12.69
14.36
13.25
10.22
12.86
13.34
14.75
13.90
11.46
13.10
13.78
12.56
12.75
12.65
14.01
13.83
14.26
15.79
14.90
14.59
12.14
11.33
11.84
10.98
13.35
12.36
10.87
12.79
10.04
11.87
9.15
12.17
12.34
13.06
12.71
11.92
13.54
13.51
12.97
11.30
12.09
11.22
7.92
11.47
8.71
12.67
12.06
15.15
12.65
11.19
12.50
11.97
14.09
12.43
11.83
10.54
Ks
11.91
13.58
12.01
11.74
11.60
12.26
13.81
12.76
9.61
12.35
12.79
14.12
13.29
10.62
12.49
12.73
11.87
12.05
11.83
13.35
13.27
13.54
14.79
13.75
13.82
11.09
10.30
11.16
10.10
12.64
11.80
9.56
12.02
8.72
10.65
8.02
11.55
11.53
12.26
11.63
11.20
12.23
13.12
12.08
10.30
10.83
9.34
7.50
10.35
7.22
10.92
10.76
14.65
12.22
9.88
11.07
11.34
13.66
11.91
11.33
9.61
d4
3.5
6.0
4.8
3.2
7.4
7.3
4.4
3.0
12.8
6.3
9.0
7.8
10.9
7.1
19.7
12.4
12.4
31.3
10.1
24.2
37.5
19.6
13.0
26.2
64.5
48.8
48.2
37.6
47.0
43.7
46.7
42.1
26.0
37.4
36.1
38.2
44.3
40.0
51.4
57.9
59.8
25.3
17.2
66.1
32.6
56.8
12.8
49.8
42.1
84.3
33.2
27.0
60.5
56.9
66.5
59.8
22.1
2.8
3.5
7.4
7.6
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 13
Table 1. continued.
RA (J2000.0) Dec
19 25 47.52 +22 26 51.3
19 26 19.04 +22 45 46.6
19 26 39.93 +21 07 05.3
19 27 01.88 +22 45 42.0
19 27 08.06 +22 46 22.5
19 27 17.94 +08 14 29.4
19 28 02.95 +17 16 43.3
19 28 19.52 +21 55 37.9
19 28 41.27 +17 48 19.9
19 29 13.09 +17 59 23.4
19 29 54.41 +18 10 26.0
19 30 00.51 +18 21 23.0
19 30 12.69 +17 48 36.5
19 30 24.47 +18 19 38.3
19 30 38.84 +18 39 09.8
19 30 56.09 +22 22 28.3
19 31 08.67 +16 49 50.5
19 32 32.88 +15 17 11.5
19 33 11.62 +17 56 59.0
19 34 31.49 +21 55 39.9
19 34 37.89 +18 25 59.3
19 37 09.65 +20 26 55.7
19 37 51.66 +24 44 08.0
19 38 52.27 +20 38 48.8
19 41 30.75 +21 56 50.2
19 42 06.83 +21 28 57.8
19 42 38.90 +22 53 24.1
19 42 54.98 +23 24 14.9
19 42 58.16 +23 24 27.7
19 43 25.03 +23 13 47.6
19 43 44.62 +23 14 44.7
19 44 05.25 +23 26 47.9
19 44 23.55 +23 59 46.4
19 44 29.90 +23 35 31.4
19 44 33.20 +23 44 30.2
19 44 42.55 +27 22 48.6
19 44 45.16 +23 44 39.5
19 45 04.72 +26 39 50.6
19 45 13.64 +23 47 09.4
19 45 13.87 +27 50 45.6
19 46 07.52 +22 31 12.3
19 46 09.56 +22 54 23.2
19 49 07.23 +21 17 42.0
19 49 28.58 +28 58 09.4
19 49 48.25 +23 53 31.8
19 50 01.48 +26 27 38.1
19 54 44.83 +33 51 53.9
19 56 12.57 +30 15 28.6
19 56 55.88 +31 56 37.0
19 57 12.42 +30 13 16.1
19 59 34.39 +32 08 48.7
19 59 35.55 +28 38 30.3
19 59 47.22 +35 30 52.9
19 59 56.42 +30 48 23.8
20 01 12.85 +28 22 11.3
20 01 53.90 +35 42 22.3
20 01 54.27 +29 28 48.4
20 01 59.69 +32 06 35.4
20 02 03.12 +32 32 45.5
20 02 33.05 +35 15 38.8
20 04 23.15 +35 40 07.1
r
17.56
17.36
14.66
17.02
16.12
17.20
19.25
18.73
16.70
16.91
17.68
18.96
18.74
19.27
13.26
17.16
19.34
14.16
17.94
17.79
17.23
18.75
19.32
19.43
18.34
17.89
18.86
13.53
18.55
19.26
18.55
14.05
19.17
18.10
18.82
19.39
19.33
18.48
19.18
19.24
17.54
15.20
16.77
17.13
16.03
16.36
18.69
18.35
16.39
13.02
16.03
15.81
17.05
17.48
17.72
17.85
18.81
16.13
17.41
18.50
18.10
i
16.56
15.77
13.82
15.49
14.60
17.03
17.57
16.88
15.49
15.70
16.15
17.20
17.27
17.51
11.35
15.45
16.97
13.27
16.69
16.20
15.87
17.30
17.72
17.98
16.73
16.02
17.07
12.30
17.30
17.74
17.20
13.54
17.50
16.93
17.60
17.94
17.94
16.93
17.64
18.03
16.04
13.69
15.99
15.86
14.94
15.34
17.34
17.42
15.30
12.22
15.00
14.95
16.25
16.44
16.55
16.50
17.39
14.62
16.73
17.23
16.60
Hα
15.71
16.28
13.79
15.98
14.93
16.28
17.53
17.56
15.47
15.87
16.21
17.74
17.18
17.90
11.95
15.97
17.80
13.24
16.87
16.59
16.22
17.59
18.08
18.00
16.90
16.62
17.50
12.55
17.48
18.16
17.52
11.78
18.08
16.94
17.77
18.25
18.19
17.43
17.95
18.28
14.70
14.12
15.05
16.03
14.94
15.41
17.67
17.45
14.95
12.10
15.03
14.58
16.09
15.90
16.40
16.61
17.55
15.10
16.26
17.50
16.97
J
14.71
13.52
12.32
12.38
11.90
15.32
14.17
14.74
13.67
13.78
13.54
14.87
14.37
13.80
8.21
12.72
13.20
11.73
14.61
13.79
13.38
14.93
15.40
15.51
14.04
12.95
14.29
10.51
15.24
15.34
14.75
11.77
14.76
14.76
15.63
15.74
15.75
14.50
14.76
15.34
9.22
11.50
13.58
13.78
13.03
13.13
15.27
15.22
13.04
10.30
12.81
12.48
14.80
13.69
14.27
14.33
15.11
11.61
13.67
14.96
14.32
H
13.92
12.52
11.47
10.97
10.68
13.99
12.57
13.82
12.43
12.73
12.16
13.36
13.02
12.16
7.28
11.94
11.77
10.98
13.51
12.80
12.20
13.68
14.55
14.43
13.08
12.04
12.81
9.56
14.43
14.08
13.36
10.30
13.72
13.65
14.37
15.02
14.33
13.68
13.57
14.17
7.19
10.79
11.88
12.97
11.97
11.74
14.20
14.25
12.19
9.31
12.07
10.32
14.01
12.16
13.05
13.20
14.12
10.75
12.80
14.01
13.25
Ks
13.23
11.90
10.95
10.04
9.90
12.76
10.88
13.25
11.48
12.06
11.20
12.49
12.07
10.96
6.60
11.36
10.70
10.20
12.77
12.21
11.41
12.48
14.01
13.75
12.47
11.38
11.79
8.62
13.86
13.36
12.28
9.08
13.11
12.99
13.65
14.52
13.36
13.03
12.92
13.35
5.97
10.24
10.49
12.23
11.25
10.62
13.54
13.43
11.58
8.10
11.53
8.27
13.04
10.91
12.20
12.37
13.53
10.08
11.98
13.49
12.56
d4
12.5
10.6
8.1
6.7
7.5
44.4
35.5
16.3
21.3
14.0
10.4
7.6
17.3
7.2
15.0
36.3
19.5
79.8
21.6
45.3
34.1
22.8
19.7
19.5
23.0
24.4
13.5
3.4
3.1
4.4
5.0
8.7
8.3
6.0
4.3
14.9
2.5
29.4
5.5
12.5
33.2
19.2
39.2
13.6
33.9
28.2
30.2
4.7
7.5
7.9
14.2
20.1
32.9
7.0
26.5
26.5
32.3
13.1
19.1
5.7
6.5
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 14
Table 1. continued.
RA (J2000.0) Dec
20 04 47.02 +35 47 09.5
20 05 00.61 +35 37 52.2
20 05 14.59 +32 21 25.1
20 05 21.89 +29 51 56.6
20 06 51.26 +27 20 37.6
20 07 07.58 +35 50 06.3
20 07 14.83 +35 36 01.9
20 07 26.84 +35 34 36.0
20 07 28.65 +36 18 29.3
20 08 11.53 +35 25 00.5
20 09 11.34 +30 34 11.7
20 10 22.77 +29 56 21.5
20 10 24.42 +31 45 16.6
20 10 57.51 +34 37 32.4
20 11 26.20 +33 16 06.8
20 11 52.98 +28 15 17.0
20 12 31.94 +32 22 14.0
20 13 07.52 +31 18 51.5
20 13 58.71 +31 42 10.8
20 14 28.69 +32 09 09.5
20 14 42.32 +32 09 03.9
20 15 50.96 +37 30 04.2
20 16 03.23 +37 14 50.6
20 16 22.09 +38 10 14.2
20 16 23.18 +37 37 04.6
20 16 48.91 +29 30 58.2
20 17 04.88 +40 48 34.2
20 17 08.12 +41 07 27.0
20 17 13.88 +42 10 44.2
20 17 15.03 +31 01 01.3
20 17 45.30 +41 50 33.2
20 17 51.21 +31 00 52.0
20 18 35.83 +40 55 08.0
20 18 43.67 +40 47 27.8
20 18 49.29 +39 35 32.0
20 18 59.19 +39 24 42.3
20 19 09.01 +33 32 40.1
20 19 11.27 +36 03 59.3
20 19 18.94 +38 14 48.5
20 19 33.95 +36 41 10.6
20 19 35.95 +39 24 43.5
20 19 45.44 +39 44 00.9
20 19 52.07 +32 41 32.3
20 20 07.87 +40 05 08.3
20 20 24.83 +38 43 17.5
20 20 58.52 +38 09 49.8
20 21 12.98 +41 01 13.1
20 22 10.20 +33 50 34.6
20 22 34.45 +40 55 46.4
20 23 41.92 +43 25 38.5
20 23 45.75 +39 04 40.2
20 24 07.29 +42 35 52.1
20 24 11.20 +42 17 09.1
20 24 21.82 +42 25 54.3
20 24 27.02 +38 55 39.0
20 24 27.13 +38 30 54.9
20 24 29.12 +39 02 27.1
20 24 31.08 +42 13 07.6
20 24 39.32 +39 56 55.2
20 24 39.59 +42 21 09.0
20 24 55.53 +42 45 04.0
r
18.85
19.34
17.24
17.41
17.98
17.95
19.24
19.39
18.20
15.58
18.39
17.95
17.82
15.68
18.93
17.39
15.27
18.36
19.31
18.06
17.39
18.07
19.01
17.40
19.34
18.80
18.36
14.29
16.76
16.00
18.12
18.52
17.24
16.97
17.04
17.58
16.34
18.27
18.61
17.97
19.35
16.36
18.29
17.96
19.18
16.20
18.03
14.38
18.73
18.38
19.25
16.98
16.33
17.43
18.11
17.87
15.07
17.75
19.03
15.90
18.90
i
17.88
17.75
17.63
16.39
16.39
16.96
18.09
17.95
17.16
15.00
17.02
16.75
15.97
14.36
17.55
15.33
14.56
16.82
17.38
16.67
16.01
16.40
17.76
16.31
17.33
16.86
16.95
12.74
15.38
15.13
16.82
17.43
16.22
15.81
16.00
16.48
15.38
16.61
17.68
16.97
17.73
15.17
16.86
16.85
17.77
14.67
16.57
12.90
17.12
17.12
17.58
15.58
15.49
16.28
17.15
16.74
14.17
16.60
17.76
14.77
16.99
Hα
17.49
18.06
14.18
16.49
16.40
16.83
18.03
17.69
16.66
14.18
17.10
16.93
16.36
14.64
17.58
15.93
14.42
16.95
17.94
16.98
16.31
15.91
17.42
16.06
17.81
17.25
17.35
13.04
15.67
15.08
16.81
16.68
15.61
15.29
15.55
16.25
15.40
17.16
16.64
16.81
17.98
14.45
17.15
16.48
18.07
14.60
16.83
13.34
17.36
17.14
17.95
15.56
15.11
16.09
16.29
16.59
14.01
16.47
17.32
14.73
17.38
J
16.04
15.67
14.96
13.76
13.47
15.14
16.46
15.99
15.06
11.31
13.86
15.50
12.87
12.08
14.34
12.30
13.13
13.96
13.66
14.24
13.38
13.08
15.45
14.84
14.06
13.86
14.85
10.15
13.06
13.54
14.72
14.67
14.75
13.94
13.59
14.76
13.70
13.16
16.04
15.10
15.43
12.98
14.18
14.85
15.17
11.88
14.24
10.58
14.87
14.64
15.32
13.16
13.61
13.59
13.40
14.85
12.42
14.85
15.42
12.65
14.43
H
15.22
14.76
12.76
12.37
12.09
14.15
15.24
15.10
14.26
10.61
12.66
14.39
11.81
10.84
12.94
10.71
12.18
12.63
12.15
13.03
12.11
11.46
14.11
13.91
12.66
12.53
13.78
9.27
11.81
12.58
13.28
13.03
13.81
13.10
12.64
13.68
12.83
11.28
14.87
14.08
14.40
11.83
13.04
14.11
14.05
10.38
13.33
9.84
14.15
13.40
14.44
12.04
12.64
12.23
11.89
13.90
11.42
13.81
14.41
11.54
13.55
Ks
14.77
14.26
10.66
11.25
11.01
13.50
14.50
14.57
13.64
9.78
11.77
13.76
10.90
9.75
11.70
9.50
10.82
11.59
10.97
12.25
11.26
9.96
13.10
13.35
11.48
11.60
13.20
8.65
10.95
12.06
12.30
11.75
12.88
12.49
11.88
13.02
12.22
9.71
14.19
13.22
13.78
10.97
12.25
13.55
13.44
8.87
12.84
9.28
13.63
12.65
13.87
11.33
11.97
11.25
10.78
13.29
10.66
13.10
13.55
10.75
12.88
d4
8.7
4.9
15.3
35.9
35.4
9.1
3.9
2.9
23.6
8.8
36.7
31.3
31.0
20.1
19.1
35.6
25.8
27.1
27.8
14.9
14.4
8.6
7.9
13.8
9.9
68.3
6.6
18.1
31.7
9.8
24.1
13.8
3.7
6.3
12.4
6.8
45.7
42.6
12.6
26.7
5.6
14.6
63.6
9.2
17.1
14.2
14.7
44.6
15.0
33.3
6.9
11.2
6.8
6.5
7.0
3.2
3.2
6.4
33.3
5.5
17.9
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 15
Table 1. continued.
RA (J2000.0) Dec
20 25 30.03 +34 45 17.5
20 25 49.86 +41 23 08.1
20 27 07.14 +39 32 48.6
20 27 09.33 +39 14 21.5
20 27 42.17 +40 30 11.1
20 27 57.89 +39 23 32.5
20 28 31.45 +39 53 20.1
20 28 34.25 +35 54 17.4
20 28 44.46 +40 11 36.7
20 28 47.71 +40 33 49.3
20 28 50.31 +40 35 49.8
20 29 16.22 +40 11 06.2
20 29 32.28 +40 13 07.5
20 29 47.93 +35 59 26.5
20 30 18.58 +38 57 13.5
20 30 33.99 +40 43 25.6
20 31 11.04 +40 20 46.5
20 31 13.75 +41 15 17.5
20 33 00.81 +40 18 00.3
20 33 01.84 +39 03 42.7
20 33 53.45 +40 54 48.9
20 34 13.39 +41 01 57.9
20 35 06.32 +47 03 22.8
20 35 26.03 +46 49 56.1
20 41 14.48 +46 01 55.9
20 41 21.02 +41 17 21.3
20 41 22.99 +45 55 41.6
20 41 34.22 +39 32 39.0
20 41 40.07 +41 12 27.9
20 45 02.36 +43 05 20.6
20 45 16.51 +41 35 26.8
20 45 29.31 +41 06 22.3
20 46 26.87 +46 18 17.8
20 46 32.98 +46 40 56.9
20 46 45.49 +41 06 59.6
20 47 04.82 +43 49 11.4
20 47 13.69 +46 35 17.5
20 47 14.21 +47 14 16.6
20 47 25.22 +43 48 32.2
20 47 33.97 +41 31 36.7
20 48 19.32 +47 20 47.3
20 48 57.79 +43 49 55.1
20 49 07.37 +45 55 18.0
20 49 56.23 +46 50 37.8
20 50 18.22 +46 53 56.4
20 50 19.55 +45 47 37.0
20 50 20.65 +45 47 21.5
20 50 22.42 +44 19 17.6
20 50 40.29 +44 30 49.1
20 50 44.99 +47 12 44.7
20 50 50.39 +44 50 11.7
20 50 53.17 +44 50 36.4
20 51 02.14 +47 12 37.4
20 51 20.99 +44 26 19.6
20 51 32.79 +44 23 48.0
20 52 00.99 +44 28 41.4
20 52 40.84 +49 58 04.1
20 52 56.75 +39 08 30.2
20 53 15.64 +43 44 22.8
20 53 56.92 +44 51 31.9
20 54 07.40 +41 34 58.0
r
18.37
18.89
16.67
17.76
18.21
16.33
14.74
15.89
16.83
16.88
17.84
17.22
15.68
14.75
17.18
18.67
16.64
19.34
17.44
16.73
18.77
19.00
16.44
18.54
18.93
19.07
18.84
15.16
17.35
15.29
17.25
16.61
18.83
17.72
18.54
18.76
14.46
17.99
17.82
18.19
16.67
18.33
16.46
16.50
19.02
18.72
17.09
18.94
14.96
18.61
14.80
18.66
18.44
15.25
16.65
16.94
18.48
18.12
17.00
18.28
15.12
i
17.04
18.06
15.45
16.45
16.86
15.20
13.82
14.42
15.57
15.56
16.25
15.91
14.80
13.74
16.12
17.00
15.45
17.67
16.27
15.31
16.92
17.75
15.23
17.17
17.98
17.53
17.72
14.11
15.74
14.13
15.78
15.47
17.71
16.48
17.46
17.53
12.85
17.08
16.57
16.88
15.87
16.84
15.49
15.46
17.50
17.20
15.94
16.97
13.83
17.55
13.44
16.78
16.62
14.10
15.43
15.60
17.00
16.59
15.93
16.56
13.77
Hα
16.88
16.99
15.43
16.54
17.09
15.29
13.45
13.81
15.27
15.74
16.70
15.94
14.76
12.98
16.04
17.37
15.24
18.04
16.00
15.33
17.33
16.54
15.48
17.53
17.32
17.49
17.91
13.39
15.99
14.08
15.99
15.59
17.58
16.61
17.14
16.71
13.13
16.52
16.10
16.38
15.82
17.27
15.07
15.38
17.65
17.67
16.01
16.79
13.78
17.48
13.69
17.09
17.21
14.09
15.31
15.60
17.45
17.01
15.30
16.96
13.77
J
14.94
15.42
12.69
13.93
14.05
12.77
11.49
11.50
13.68
13.00
13.66
13.96
13.16
10.96
14.16
13.98
13.24
14.56
14.21
12.78
13.04
13.23
12.73
14.72
15.74
15.55
15.71
12.12
12.82
12.51
13.18
13.38
15.99
14.10
15.61
15.34
10.05
15.14
13.35
14.92
14.29
13.60
13.72
13.51
15.29
15.78
13.81
13.91
11.52
15.40
15.41
14.02
13.80
11.88
13.34
13.55
14.18
14.71
14.07
13.90
14.62
H
13.60
13.85
11.53
12.76
12.94
11.48
10.43
10.08
12.69
11.71
12.09
12.99
12.31
9.44
13.17
12.60
12.04
13.36
13.17
11.54
11.70
11.29
11.38
13.66
14.91
13.87
14.87
10.99
11.43
11.35
12.03
12.05
14.92
13.26
14.22
14.34
8.93
14.29
12.21
14.09
13.48
12.26
12.93
12.59
13.96
14.67
12.80
12.73
10.42
14.26
13.10
12.89
12.36
10.96
12.27
12.49
13.34
13.82
13.21
12.80
12.82
Ks
12.70
12.30
10.76
12.04
12.26
10.42
9.56
8.29
12.12
10.74
10.91
12.42
11.85
8.14
12.56
11.67
11.21
12.66
12.62
10.53
10.86
9.86
10.15
12.95
14.28
12.74
14.33
10.20
10.46
10.57
11.34
11.08
14.26
12.60
13.03
13.76
7.48
13.66
11.35
13.58
12.95
11.40
12.53
12.04
12.88
13.77
12.22
12.09
9.55
13.58
11.10
12.28
11.46
10.30
11.63
11.90
12.68
13.31
12.54
12.20
11.28
d4
49.0
17.9
17.6
13.2
17.9
12.7
18.3
45.6
7.0
14.5
14.9
6.9
8.7
48.1
29.1
23.1
13.7
30.8
22.8
42.6
18.4
20.5
32.1
31.5
18.0
34.7
14.4
15.6
32.7
28.6
24.1
19.8
8.1
16.7
21.8
1.6
14.6
16.8
3.4
27.4
14.7
18.7
15.3
9.5
6.3
17.9
18.1
14.5
11.7
6.4
17.4
17.6
6.7
7.3
7.7
7.9
39.9
57.0
29.4
12.3
40.6
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 16
Table 1. continued.
RA (J2000.0) Dec
20 54 33.18 +48 46 30.8
20 54 38.00 +49 13 30.9
20 54 46.91 +44 48 19.9
20 54 54.34 +44 43 43.0
20 54 58.07 +47 45 51.7
20 55 03.02 +44 10 52.1
20 55 03.99 +44 44 26.6
20 56 47.90 +46 24 34.5
20 57 20.26 +42 23 19.4
20 57 30.09 +49 32 58.0
20 57 36.62 +52 21 17.1
20 57 37.30 +44 06 44.0
20 57 40.95 +46 59 45.1
20 57 59.87 +43 53 26.1
20 58 01.38 +43 45 20.2
20 58 02.67 +46 35 02.6
20 58 12.19 +46 21 49.0
20 58 21.54 +43 53 44.9
20 58 27.02 +43 53 20.1
20 58 42.07 +46 24 59.8
20 59 06.70 +44 18 23.9
21 00 19.06 +52 27 28.3
21 00 21.42 +52 27 09.6
21 01 10.58 +52 15 12.9
21 03 32.56 +47 48 39.4
21 03 50.13 +50 10 23.7
21 03 58.92 +50 14 51.4
21 04 04.87 +53 51 24.4
21 04 06.83 +50 13 18.0
21 04 27.91 +52 22 03.3
21 04 28.81 +50 18 24.6
21 04 54.56 +50 17 51.9
21 05 28.26 +51 36 00.8
21 06 12.87 +51 21 41.3
21 06 13.61 +50 23 22.8
21 07 10.22 +48 57 29.3
21 10 28.25 +44 58 41.8
21 10 53.52 +51 13 44.0
21 11 25.36 +46 57 53.1
21 13 17.53 +51 14 30.2
21 13 18.30 +46 20 17.9
21 15 58.05 +47 57 46.5
21 16 22.51 +51 34 41.8
21 16 41.03 +51 30 05.4
21 16 45.67 +47 15 36.5
21 18 18.24 +42 53 52.3
21 19 34.02 +46 47 45.5
21 19 36.96 +46 49 09.0
21 19 38.96 +46 49 13.6
21 19 47.43 +53 22 25.1
21 19 56.24 +51 47 04.2
21 20 25.15 +51 46 30.7
21 20 36.52 +51 51 26.0
21 20 48.00 +53 40 51.3
21 21 24.55 +52 49 55.1
21 21 45.31 +46 54 57.9
21 21 54.68 +46 38 56.7
21 21 59.94 +49 26 24.2
21 22 00.51 +46 54 32.7
21 22 09.02 +49 26 24.6
21 22 14.73 +49 05 38.8
r
16.47
19.39
17.02
17.79
14.69
16.41
17.80
17.33
17.12
16.21
15.78
17.94
15.79
14.68
16.52
19.05
18.31
16.69
17.42
16.42
17.20
14.61
14.06
17.07
16.81
18.80
15.85
18.21
16.33
16.88
19.01
16.48
18.09
18.83
17.60
15.06
16.70
17.06
16.45
17.39
19.33
18.32
19.48
18.88
17.33
17.62
16.54
16.79
18.84
16.13
18.97
18.30
18.55
17.03
17.68
17.45
16.89
18.17
15.69
16.09
19.07
i
15.34
17.86
15.63
16.21
13.76
14.95
16.39
15.77
15.54
14.87
14.58
16.49
14.43
13.75
15.26
17.73
16.73
15.23
16.14
15.13
16.17
13.60
12.88
15.54
15.66
16.67
14.39
16.63
15.12
15.37
16.75
15.24
16.07
17.00
16.34
13.60
15.76
15.62
15.34
15.89
17.98
16.77
17.55
17.45
16.17
16.15
15.39
15.28
17.63
14.64
17.51
16.80
17.39
15.39
16.19
15.94
15.68
16.05
14.25
14.79
17.43
Hα
15.39
18.07
15.88
16.04
13.66
15.15
16.35
16.15
15.91
15.16
14.37
16.40
14.62
13.54
15.23
17.80
17.21
15.35
16.04
15.17
16.15
13.55
12.84
15.49
15.39
17.45
14.80
15.81
15.16
15.65
17.35
14.89
16.66
17.38
16.42
14.01
15.22
15.99
15.33
16.02
18.33
17.18
18.16
17.72
15.82
16.13
15.38
15.52
17.15
14.94
16.92
17.11
17.40
15.84
16.59
16.24
15.76
16.72
14.54
15.12
17.51
J
13.39
15.49
12.88
14.04
12.28
12.43
14.31
13.14
12.90
13.15
12.45
13.85
12.26
11.85
13.11
15.62
14.24
12.80
14.02
13.04
14.22
11.69
11.15
13.06
13.62
13.85
12.24
13.43
12.71
12.16
13.98
13.29
12.91
14.52
14.24
11.35
14.02
13.35
13.51
13.34
15.04
14.48
15.25
15.35
14.58
13.58
13.12
12.09
15.06
12.08
15.20
14.69
14.87
12.72
13.99
13.79
14.28
13.58
11.21
12.25
14.01
H
12.68
14.21
11.52
13.18
11.54
11.11
13.31
12.19
11.82
12.46
11.44
12.91
11.57
10.87
11.87
14.34
13.33
11.49
12.92
12.32
13.29
10.63
10.22
12.04
12.59
12.80
11.06
12.40
11.78
11.10
12.96
12.07
11.84
13.20
13.37
10.55
13.10
12.63
12.46
12.10
13.91
13.25
14.30
14.29
13.66
12.62
12.19
10.88
13.56
11.16
14.03
13.78
13.53
11.85
13.23
12.69
13.18
12.78
9.79
10.27
12.89
Ks
12.10
13.13
10.31
12.74
10.77
10.25
12.59
11.59
11.24
11.84
10.76
12.16
10.99
10.25
11.05
13.20
12.72
10.71
12.25
11.74
12.75
9.81
9.40
11.29
11.81
12.23
10.35
11.61
11.10
10.42
12.42
11.14
11.06
12.39
12.80
9.97
12.60
12.05
11.76
11.29
13.24
12.20
13.79
13.58
13.12
11.98
11.69
10.04
12.29
10.56
13.01
13.30
12.51
11.24
12.71
12.07
12.40
12.29
8.59
8.71
12.25
d4
36.8
29.2
7.1
6.0
20.2
26.3
6.5
13.1
51.2
18.6
24.4
16.3
21.9
7.7
9.5
14.2
7.6
7.3
7.8
10.4
21.8
5.8
5.6
11.2
20.5
6.5
4.0
54.6
3.9
33.6
4.8
7.1
38.0
35.3
18.4
16.5
34.2
37.1
17.0
29.9
25.1
27.3
14.6
14.2
25.2
24.4
1.7
1.4
1.5
29.4
5.0
5.1
1.3
30.8
29.2
5.0
15.1
16.6
4.6
16.6
19.4
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 17
Table 1. continued.
RA (J2000.0) Dec
21 22 18.11 +46 57 11.2
21 23 50.19 +50 08 18.2
21 26 20.32 +55 25 51.8
21 29 55.57 +55 39 04.1
21 31 05.96 +51 25 31.8
21 31 08.81 +51 59 45.3
21 31 25.07 +49 18 35.5
21 31 29.48 +48 09 54.7
21 33 17.78 +57 48 13.5
21 34 31.56 +54 16 11.8
21 34 51.70 +57 51 40.5
21 34 53.08 +57 51 25.1
21 35 16.89 +57 32 42.3
21 38 06.68 +55 20 46.4
21 38 10.00 +57 23 52.8
21 38 12.64 +57 20 33.7
21 39 29.40 +57 06 30.7
21 39 51.88 +57 26 58.3
21 39 52.16 +58 14 12.9
21 39 52.23 +52 25 15.2
21 39 54.07 +57 29 33.5
21 39 58.44 +58 12 14.8
21 40 11.35 +57 39 51.8
21 40 21.30 +57 26 57.9
21 40 36.90 +58 14 37.9
21 40 42.81 +58 19 37.4
21 40 55.93 +57 17 59.2
21 41 15.97 +58 08 26.5
21 41 39.49 +50 17 49.8
21 42 02.30 +54 43 31.9
21 42 17.63 +56 55 50.2
21 43 06.36 +51 06 10.6
21 44 18.19 +47 23 44.2
21 44 33.16 +57 37 32.7
21 44 41.34 +57 46 11.9
21 44 43.70 +57 14 19.8
21 45 47.74 +56 48 45.8
21 46 00.27 +57 23 09.6
21 46 25.99 +57 28 28.9
21 46 40.27 +47 13 27.6
21 48 11.78 +57 59 41.6
21 49 33.64 +57 45 02.2
21 53 31.40 +56 29 27.0
21 53 45.14 +59 43 42.0
21 54 47.24 +53 13 47.0
21 56 28.47 +57 14 45.5
21 58 12.70 +52 26 21.6
21 58 18.39 +55 26 31.9
21 58 20.72 +55 26 32.6
21 58 58.32 +52 46 03.0
21 59 36.96 +55 24 33.4
22 01 08.17 +55 54 41.4
22 02 10.21 +58 45 44.6
22 03 13.49 +59 39 57.2
22 03 30.08 +58 28 04.2
22 05 13.54 +57 25 53.5
22 06 09.07 +60 42 41.4
22 06 48.59 +54 11 47.5
22 07 15.51 +55 12 39.2
22 08 02.26 +60 59 05.6
22 09 43.15 +58 56 22.7
r
18.20
19.07
16.80
17.81
18.07
19.05
18.04
15.97
14.63
15.41
18.49
18.73
17.93
16.16
18.99
17.73
18.13
19.36
17.12
19.04
17.76
17.37
17.65
16.95
14.85
19.00
17.78
18.20
17.84
19.36
16.69
18.12
16.27
17.98
17.19
18.14
19.06
17.15
18.04
17.25
16.71
16.70
18.79
18.25
18.32
15.14
19.12
19.31
19.29
19.17
17.96
16.14
17.31
17.62
14.90
19.10
16.28
18.67
19.31
17.92
17.98
i
16.17
17.45
15.89
16.52
16.33
17.32
17.50
14.77
13.96
13.94
16.77
17.20
16.50
14.78
17.06
16.37
16.54
17.23
15.91
17.93
16.36
15.70
16.15
15.92
13.77
17.08
16.16
16.71
16.93
17.86
15.32
17.63
15.32
16.54
16.00
17.33
16.88
15.72
16.96
15.84
15.43
15.35
18.13
16.84
17.27
14.38
17.86
18.08
17.97
18.37
16.59
15.36
15.93
16.20
13.92
18.04
15.03
17.42
17.77
16.50
16.60
Hα
16.23
17.62
15.81
16.15
16.86
17.79
16.36
14.96
13.68
14.31
17.22
17.38
16.16
15.16
17.50
16.02
16.96
17.90
15.79
18.08
16.65
16.12
16.61
15.93
13.87
17.25
16.06
16.72
16.76
18.04
15.64
17.29
15.36
16.94
16.23
17.13
17.54
16.06
15.68
16.07
15.50
15.66
16.47
17.12
16.78
13.48
17.92
17.87
18.05
17.68
16.93
14.99
16.29
16.43
13.91
17.56
15.14
17.22
18.13
16.51
16.95
J
13.55
14.38
13.74
14.19
13.83
14.60
14.85
13.28
12.25
11.97
14.33
14.71
14.44
12.73
14.87
14.53
14.50
14.93
13.90
15.60
14.72
13.42
14.31
14.50
11.90
13.94
13.81
14.47
15.41
15.29
12.43
15.07
13.19
14.34
14.17
16.35
14.33
12.65
14.07
13.37
12.92
13.14
14.94
14.82
15.43
12.97
15.88
15.71
15.32
16.47
14.37
13.03
13.96
13.85
12.07
15.12
13.05
16.48
16.53
15.13
13.81
H
12.76
12.83
12.47
12.74
12.88
13.29
13.71
12.37
10.96
11.21
13.25
13.48
13.56
11.99
14.09
13.64
13.72
14.16
12.86
14.60
13.87
12.35
13.44
13.40
10.89
12.54
12.83
13.30
14.72
13.97
11.53
14.15
12.13
13.44
13.09
15.05
13.40
11.46
13.06
12.25
11.66
12.43
13.30
13.91
14.16
11.83
15.02
14.42
13.99
15.43
13.62
11.62
13.22
12.88
11.16
14.09
11.62
15.44
15.35
14.16
12.64
Ks
12.32
11.73
11.36
11.38
12.21
12.34
12.88
11.82
9.83
10.63
12.65
12.68
13.07
11.46
13.70
13.17
13.33
13.56
12.29
13.85
13.28
11.76
12.97
12.62
10.23
11.64
12.24
12.53
14.33
13.06
11.02
13.54
11.54
12.86
12.39
13.80
12.82
10.63
12.30
11.50
10.84
11.86
12.06
13.35
13.10
10.31
14.37
13.64
13.00
14.63
13.19
10.43
12.57
12.29
10.64
13.55
10.39
14.46
14.44
13.55
11.84
d4
5.9
28.4
11.9
26.7
34.9
41.5
34.7
24.0
12.7
23.3
9.4
9.5
7.4
20.0
10.1
10.0
13.6
1.6
4.7
44.5
2.1
4.3
7.1
3.6
3.7
6.7
7.3
8.4
29.8
20.7
8.6
28.0
47.6
14.3
16.3
12.6
10.3
10.9
12.0
50.2
15.2
17.4
19.0
13.9
31.5
24.5
15.8
10.6
10.4
13.4
12.3
11.0
24.4
7.5
21.8
22.4
20.8
20.3
19.2
7.5
14.2
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 18
Table 1. continued.
RA (J2000.0) Dec
22 11 00.10 +60 56 33.5
22 11 46.04 +60 42 03.6
22 11 54.94 +58 57 22.1
22 12 13.10 +58 52 02.8
22 12 32.53 +60 42 50.3
22 13 11.17 +54 25 31.4
22 13 16.57 +56 12 13.5
22 13 20.22 +60 29 29.2
22 13 34.04 +60 35 58.7
22 13 49.64 +55 54 07.3
22 13 51.53 +60 44 24.8
22 13 59.71 +60 35 06.2
22 14 11.56 +61 26 06.4
22 14 19.27 +60 38 06.7
22 14 28.89 +61 25 24.0
22 14 39.83 +61 25 58.8
22 14 40.31 +61 26 13.8
22 14 42.24 +60 44 02.5
22 15 08.95 +61 02 41.1
22 15 11.99 +57 52 51.4
22 15 18.87 +58 23 12.6
22 15 37.63 +61 06 55.1
22 16 02.80 +56 14 27.3
22 16 21.24 +60 06 30.4
22 16 39.34 +60 47 57.4
22 16 44.69 +60 48 42.1
22 16 55.98 +60 53 43.7
22 17 34.33 +61 14 08.8
22 17 40.25 +61 47 02.5
22 17 55.42 +61 02 05.9
22 18 08.49 +56 05 53.3
22 18 18.15 +56 06 09.7
22 18 25.73 +61 37 26.5
22 19 03.17 +61 37 56.4
22 19 11.20 +60 58 01.6
22 19 11.45 +56 02 53.3
22 19 14.69 +61 38 47.5
22 20 53.13 +58 48 43.9
22 25 48.46 +61 23 54.5
22 27 00.27 +56 17 32.5
22 28 00.09 +63 09 08.9
22 31 50.40 +59 12 46.0
22 31 51.98 +63 10 46.9
22 36 45.28 +61 52 52.2
22 37 03.73 +58 58 49.4
22 37 28.63 +58 37 53.1
22 38 19.84 +62 12 12.1
22 38 53.88 +61 56 28.9
22 40 55.96 +61 31 09.3
22 42 14.74 +59 49 52.6
22 44 13.21 +61 00 45.1
22 45 08.11 +59 11 23.0
22 45 18.08 +61 30 49.9
22 46 38.35 +61 08 09.0
22 47 14.25 +59 21 49.1
22 47 22.39 +58 01 21.5
22 49 06.90 +62 07 34.8
22 49 08.54 +61 24 06.8
22 52 50.89 +62 36 17.3
22 53 26.79 +62 35 31.7
22 53 31.30 +62 37 11.4
r
17.69
17.25
18.84
17.34
17.43
17.80
17.71
18.04
18.79
19.08
18.43
16.40
17.56
19.32
17.68
17.69
15.33
19.43
17.02
17.83
19.00
16.81
17.42
18.58
18.10
18.81
17.93
19.43
17.73
18.67
13.73
17.78
18.46
15.70
18.86
19.11
18.34
15.46
19.20
16.51
16.96
16.09
19.09
19.50
16.20
18.53
16.71
16.72
19.43
17.91
18.32
18.30
17.37
17.03
17.22
14.00
16.89
19.40
18.45
18.43
18.31
i
16.48
16.22
16.97
16.30
16.37
17.64
16.53
16.74
17.35
18.34
17.02
15.30
16.41
18.04
16.26
16.20
14.14
17.57
15.85
17.08
17.64
15.61
16.56
17.47
16.61
17.39
16.40
17.92
16.30
17.01
13.02
16.64
16.67
14.65
17.20
18.03
16.99
14.10
17.65
15.64
15.64
14.80
17.14
17.64
14.55
16.17
15.68
15.48
17.86
16.82
16.95
16.66
16.19
15.79
15.69
12.95
15.54
18.07
17.17
16.58
16.68
Hα
16.26
16.07
17.68
15.65
16.41
15.89
16.66
17.03
17.50
17.57
16.84
15.45
16.43
17.96
16.63
16.57
14.22
17.79
15.84
16.14
17.30
15.66
15.79
17.59
17.06
16.98
16.33
17.61
16.15
17.36
12.54
16.72
17.21
14.69
17.42
17.85
17.14
14.30
17.77
15.12
15.96
15.01
17.42
17.72
15.12
16.76
15.44
15.60
17.49
16.98
17.11
17.17
15.67
15.46
15.78
12.85
15.82
17.88
17.22
17.07
16.73
J
14.19
14.32
13.95
13.41
13.84
16.59
13.80
14.69
14.69
15.97
13.96
12.98
14.42
15.62
13.80
13.65
11.91
15.23
14.01
14.98
14.86
13.48
14.45
15.14
13.51
14.85
13.57
15.28
12.83
14.69
11.38
14.56
14.46
12.98
13.78
15.83
14.60
11.29
14.77
13.78
13.50
12.77
14.62
14.70
12.57
13.33
13.83
13.52
15.31
14.94
14.37
13.98
14.32
13.83
12.40
10.80
13.06
15.53
14.92
13.85
14.01
H
13.13
13.42
12.57
11.96
12.86
15.14
12.88
13.49
13.64
15.02
12.68
11.94
13.04
14.33
12.54
12.50
10.66
14.31
12.82
13.47
13.22
12.50
13.36
13.94
12.33
13.77
12.19
14.06
11.50
13.70
10.18
13.52
13.60
11.79
11.74
14.92
13.87
9.84
13.80
12.86
12.51
11.54
13.68
13.49
11.79
12.43
12.55
12.43
14.34
14.15
13.25
12.44
13.36
12.84
10.78
9.76
11.96
14.48
13.70
12.75
12.84
Ks
12.46
12.81
11.53
10.83
12.30
14.19
12.25
12.84
13.04
14.32
11.99
11.35
12.12
13.27
11.70
11.81
9.77
13.84
12.13
11.97
11.62
11.89
12.70
12.78
11.51
13.15
11.27
13.39
10.52
13.13
9.03
12.80
13.16
11.11
10.20
14.26
13.34
8.63
13.14
12.11
11.86
10.85
13.17
12.80
11.40
11.88
11.50
11.69
13.66
13.73
12.45
11.11
12.74
12.28
9.53
8.85
11.22
13.83
12.97
12.14
12.11
d4
16.3
9.3
10.3
10.4
8.7
26.6
16.4
8.3
6.2
15.0
7.9
6.0
3.0
5.9
1.6
1.2
1.3
7.3
7.0
14.3
16.5
4.3
11.1
28.5
5.5
5.5
7.3
11.2
11.5
12.2
8.1
7.2
5.2
4.0
12.5
9.0
4.8
19.1
24.5
23.6
17.0
19.8
27.8
21.7
18.3
19.6
19.8
22.6
31.4
29.4
19.3
26.8
21.5
10.5
15.8
8.3
14.3
15.7
5.8
3.1
2.5
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 19
Table 1. continued.
RA (J2000.0) Dec
22 53 50.55 +61 32 46.4
22 53 51.96 +62 34 35.7
22 53 52.02 +62 38 09.0
22 53 52.17 +62 37 46.3
22 54 07.57 +62 38 51.5
22 54 09.88 +62 57 42.9
22 54 37.74 +62 29 30.8
22 54 52.08 +61 59 03.0
22 55 09.51 +62 41 23.2
22 55 21.80 +62 37 53.5
22 55 22.50 +62 28 25.2
22 55 26.19 +62 39 34.0
22 55 36.82 +62 11 15.8
22 55 37.20 +63 00 04.9
22 55 38.17 +62 36 06.3
22 55 39.41 +62 37 39.0
22 55 52.04 +62 36 52.1
22 55 53.65 +58 14 31.3
22 55 58.51 +58 40 57.9
22 55 59.58 +62 37 57.5
22 56 02.82 +62 45 13.8
22 56 13.18 +62 35 33.1
22 56 17.55 +58 44 21.5
22 56 23.13 +62 43 54.2
22 56 26.03 +62 39 00.9
22 56 28.04 +63 08 34.1
22 56 30.87 +62 42 15.7
22 56 30.91 +58 24 47.4
22 57 12.85 +59 46 48.2
22 57 25.85 +62 56 29.0
22 59 06.10 +62 46 30.0
23 00 34.78 +62 34 36.3
23 01 37.10 +61 26 13.3
23 01 51.49 +61 40 54.2
23 03 14.95 +63 12 51.8
23 03 27.99 +62 31 06.8
23 03 42.17 +61 18 50.4
23 03 46.02 +61 48 46.2
23 04 03.38 +61 51 37.5
23 04 12.45 +59 39 54.0
23 04 13.56 +59 57 27.0
23 04 39.95 +62 26 19.8
23 06 02.00 +60 12 38.7
23 06 38.25 +62 32 04.1
23 07 56.11 +62 24 14.4
23 08 18.22 +58 34 14.9
23 08 45.42 +62 27 12.5
23 08 47.33 +58 25 07.5
23 10 47.31 +62 36 28.7
23 11 42.83 +66 00 11.3
23 11 59.45 +59 53 26.5
23 12 01.75 +63 41 05.7
23 12 03.04 +60 18 38.6
23 12 04.71 +62 46 00.3
23 12 23.26 +61 43 18.4
23 13 07.09 +59 02 47.9
23 13 19.53 +59 50 16.2
23 15 26.39 +64 22 25.2
23 15 56.90 +61 45 16.9
23 16 10.45 +62 13 03.4
23 16 40.86 +62 20 57.1
r
17.93
18.42
16.67
18.39
18.48
18.56
18.37
18.94
17.87
15.96
17.59
19.31
18.08
18.95
19.13
19.06
18.52
18.44
17.66
17.95
16.85
15.24
17.54
18.76
17.57
19.24
19.10
18.26
18.05
19.34
17.55
18.56
18.06
18.11
18.63
17.09
17.55
14.61
16.35
17.92
18.47
18.42
19.27
16.35
19.41
19.43
19.05
18.25
18.62
17.84
19.10
18.50
17.68
15.23
18.08
14.49
18.55
18.48
17.75
19.38
16.78
i
16.48
16.78
15.42
16.81
16.72
17.35
16.78
17.12
16.38
14.81
16.33
17.26
16.67
17.34
17.45
16.93
17.25
17.28
15.73
16.83
15.57
14.04
16.38
17.00
16.11
17.89
16.69
16.60
16.75
17.80
16.41
17.01
16.58
16.54
17.52
15.43
15.66
13.50
15.18
16.55
17.29
16.77
18.31
14.89
17.20
18.35
17.09
17.14
16.76
15.99
18.01
16.88
16.13
14.01
16.33
13.66
17.34
17.15
16.74
17.68
15.68
Hα
16.82
16.57
15.62
17.02
17.06
17.47
16.85
17.50
16.07
14.71
16.43
17.75
16.84
17.33
17.80
17.33
16.99
16.32
16.37
16.44
15.37
14.19
16.20
17.38
16.39
17.87
17.26
17.03
16.98
17.76
15.83
17.13
16.82
16.99
17.27
15.90
15.52
13.54
15.13
16.90
17.34
17.27
17.81
15.24
17.65
18.51
17.43
17.23
17.02
16.64
17.96
17.37
16.44
14.18
16.67
13.62
17.59
17.32
16.22
17.65
15.82
J
14.23
14.24
13.36
14.02
13.55
14.35
14.08
14.09
13.87
12.69
14.19
14.57
14.66
14.46
15.05
14.08
15.08
14.98
13.09
14.82
13.34
11.80
13.93
14.45
13.61
15.61
13.48
13.57
14.51
14.53
14.32
14.86
13.50
14.62
16.02
12.52
13.04
11.36
13.01
14.54
15.26
14.33
16.23
12.25
14.26
16.44
14.34
15.00
14.05
13.66
15.95
13.91
13.06
11.92
13.98
11.79
15.05
14.61
14.82
15.35
14.15
H
13.15
13.09
12.15
12.91
12.17
13.27
12.96
12.75
12.70
11.38
13.07
13.66
13.31
13.17
13.76
12.97
13.97
13.90
12.37
13.95
12.28
10.78
12.58
13.32
12.39
14.51
12.50
11.95
13.37
13.54
13.21
13.37
12.01
13.76
14.46
11.15
11.81
10.18
11.79
13.40
14.20
13.02
15.41
10.93
13.41
15.58
13.30
13.97
12.88
12.81
14.71
12.12
11.39
11.20
13.05
10.54
14.11
13.59
13.56
14.58
12.86
Ks
12.43
12.38
11.37
12.20
11.25
12.58
12.37
11.98
11.97
10.44
12.33
13.06
12.32
12.24
12.85
12.29
13.33
13.33
11.93
13.34
11.63
10.12
11.63
12.68
11.73
13.68
11.92
10.66
12.70
13.01
12.56
12.47
10.99
13.26
13.24
10.29
11.12
9.33
10.97
12.79
13.57
12.22
14.73
9.99
12.90
15.13
12.68
13.22
12.23
12.28
13.90
10.79
10.15
10.65
12.53
9.39
13.31
12.83
12.63
13.93
11.89
d4
22.8
3.0
1.5
1.4
2.1
12.2
7.3
23.7
3.0
2.5
7.9
2.6
17.6
6.7
2.2
1.9
1.9
20.3
12.2
2.3
2.0
3.4
12.6
2.0
2.6
10.2
2.0
14.1
11.1
11.6
10.6
13.4
6.9
12.9
9.7
19.1
16.6
4.6
6.3
17.5
16.2
16.4
6.8
14.5
12.0
11.7
9.8
13.6
17.4
48.5
11.4
38.5
14.4
24.9
9.5
19.4
7.7
32.1
17.2
6.7
5.8
R. L. M. Corradi et al.: IPHAS and the symbiotic stars. I., Online Material p 20
Table 1. continued.
RA (J2000.0) Dec
23 17 35.92 +63 45 06.4
23 18 26.54 +59 53 46.6
23 18 36.35 +64 04 06.5
23 20 05.35 +62 18 41.7
23 22 27.11 +59 03 11.3
23 24 08.30 +59 17 52.9
23 26 40.12 +62 18 58.1
23 29 07.04 +59 34 30.4
23 29 37.83 +62 13 07.3
23 30 35.06 +59 55 26.0
23 32 44.44 +61 44 10.8
23 35 42.67 +62 12 28.5
23 36 18.62 +62 37 08.9
23 39 24.79 +61 59 40.9
23 40 39.28 +61 35 45.2
23 41 25.21 +65 40 42.6
23 41 33.78 +63 53 23.4
23 46 58.61 +59 01 43.2
23 47 32.55 +63 23 46.3
23 48 35.75 +66 30 53.4
23 51 05.38 +62 52 03.8
23 53 05.89 +60 21 12.7
23 56 09.52 +65 57 23.7
23 56 57.56 +58 30 34.9
23 57 27.29 +58 28 42.1
23 57 34.77 +64 46 49.1
23 58 12.52 +62 54 34.9
23 59 19.98 +66 23 12.0
r
16.08
19.18
17.68
17.59
19.17
19.45
15.78
17.36
17.85
19.15
17.48
18.18
17.76
18.57
18.45
15.03
16.06
17.32
16.80
15.71
18.80
19.27
18.46
16.75
17.76
14.43
18.47
14.63
i
14.62
18.10
16.43
16.22
18.05
18.12
14.81
15.79
16.32
17.69
16.32
16.48
16.57
16.89
17.14
13.39
14.52
16.19
15.05
14.71
17.56
17.51
16.53
14.64
16.65
13.44
17.39
13.32
Hα
14.30
18.11
16.46
16.32
18.20
18.12
14.77
16.07
15.85
17.71
16.35
17.08
16.76
17.37
17.15
13.55
14.94
16.23
15.57
14.67
17.81
17.99
17.04
15.22
15.81
13.47
17.42
13.32
J
12.20
16.10
13.92
13.91
16.19
15.93
13.13
12.41
14.10
15.36
14.17
14.44
14.82
14.34
14.88
10.50
12.31
14.38
12.76
12.95
15.53
14.41
13.92
12.18
13.30
11.49
15.52
11.06
H
10.72
14.92
12.65
12.81
15.33
14.85
12.18
10.70
13.34
14.34
13.32
13.58
13.68
13.08
13.76
8.82
11.13
13.30
11.83
11.91
14.52
13.01
13.07
11.31
11.92
10.55
14.65
9.82
Ks
9.39
14.15
11.57
12.19
14.77
13.97
11.47
9.43
12.84
13.74
12.67
13.15
13.03
12.18
13.13
7.45
10.44
12.54
11.26
11.29
13.95
12.03
12.46
10.83
11.01
9.88
14.00
8.99
d4
17.3
19.4
18.0
20.8
20.3
19.4
17.8
24.3
11.8
28.9
12.9
15.6
13.6
10.8
16.2
50.9
27.8
18.8
6.5
44.3
11.9
23.4
23.5
29.0
29.6
20.6
19.9
29.9
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