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1990ApJS...74..181Zoonematkermani+
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1990ApJS...74..181Zoonematkermani+
(OCR+proof by H.Andernach 4/97+9/98)

A catalog of small-diameter radio sources in the Galactic plane

Zoonematkermani S. and Helfand D. Becker R.H., White R.L., Perley R.L.

S. Zoonematkermani and D. J. Helfand
Columbia Astrophysics Laboratory, Columbia University

R. H. Becker
Department of Physics, University of California at Davis and
Institute of Geophysics and Planetary Physics
Lawrence Livermore National Laboratory

R.L. White
Space Telescope Science Institute and

R.A. Perley
NRAO, Socorro, NM, USA

Abstract

A survey of the Galactio plane in the longitute range -20 <= l <= 120o for Galactic latitude |b| <= 0.8o has been carried out at 1400 MHz using the VLA in the B configuretion. We present here a catalog of the 1992 discrete sources detected in this survey which is ~75% complete to a limiting peak flux density of 25 mJy for sources smaller than ~20" in diameter although sources as faint as 8 mJy and as large as 90" are also included. The catalog includes for each entry a position accurate to <= 3', peak and integrated flux densities, source extent, and information on counterparts both from earlier radio surveys of the plane (for which a comprehansive bibliography is included) and from the IRAS PSC. An extensive analysis of the integrity and completeness of the survey os presented here; in separate publications, we discuss the source content of the survey as derived from statistical analyses of the spatial distribution of the sources and from radio, optical and IR followup observations.

1. Introduction

Most of the Galactic disk will remain forever hidden from optical observers as a result of obscuration by interstellar dust. As a result, much of what we know concerning the extent, dynamics, and source populations of the Milky Way has been derived from observations in the two spectral regimes in which the dust is transparent from 100 MHz to 300 GHz and from 1-100 um. The IRAS all-sky survey has provided us with a new view of the Galaxy, detecting thousands of discrete sources within a few degrees of the plane in the far infrared (12, 25, 60 and 100 um) with a spatial resolution of ~1'; the dominant source populations are compact HII regions and evolved stars, as well as external galaxies. We present here a radio survey of the plane with a sensitivity well-matched to the IRAS data. The first radio surveys of the Galaxy were conducted nearly forty years ago. Since then, over a dozen major continuum surveys at frequencies ranging from 400 MHz to 10 GHz have been carried out using single dishes with apertures of from 45 m to 100 m. A bibliography of this work along with the parameters of each survey are presented in Table 1. The limiting sensitivities of such surveys are set by source confusion and typically fall in the range 0.5 - 2 Jy. The principal source populations detected are HII regions, supernova remnants, and extragalactic nonthermal sources, with few if any stars recorded. Recently, an interferometric survey of the northern sky with an angular resolution of 5" has been completed using the Texas 385 MHz interferometer (Douglas 1980; Douglas, priv. comm.), although its sensitivity is still limited to > 0.25 Jy. In addition, an interferometric survey of a portion of the galactic plane is being conducted at 408 MHz and 1400 MHz using the four-element telescope at the Dominion Radio Astronomy Observatory; although its sensitivity is far higher than previous surveys, source confusion in the plane is a limiting factor for most fields observed. A Westerbork survey of the northern plane is also in progress.

Despite the very large gain in sensitivity and angular resolution it can provide, the NRAO Very Large Array has not, until recently, been employed to survey the Galaxy. We present here the first of several Galactic plane surveys which are in progress using this instrument. In sect. 2, we describe the observations and their analysis. The following sections present the catalogue of 1992 sources we have derived from these data, and discuss the completeness and integrity of the survey. In IV we provide annotation to the catalogue based on a comparison with previous radio surveys, the IRAS point source catalogue, and other compilations of astronomical objects. Future papers (Paper II - Becker et al. 1990, Paper III - White et al. 1990) will report on source identifications derived from radio, optical, and infrared followup work.

2. Observation and Data Analysis

Most of the observations on which our survey is based were originally collected by Perley and Dicke as part of a project to identify relatively bright compact sources in the Galactic plane for use in HI absorption studies; Garwood et al. (1988) have recently published a partial analysis of these data. A majority of the observations we have used were carried out in 1983 December although approximately 10% of the fields were observed in 1989 March; Table 2 presents a list of these more recent pointings. Field centers were spaced every 0.5d in galactic longitude (equal to the FWHM of the primary beam) from l = 340d - 0d - 120d in three strips centered at b = 0d and b = +-0.5d for a total of 843 fields. For the southernmost fields (l<=10d) the A/B configuration was used; the remainder of the data were collected in the B configuration yielding a typical angular resolution of ~5". Each field was observed for ~2 min in two independent 3 MHz bandpasses (right and left circular polarizations) at each of two frequencies (1441.5 and 1611.7 MHz). (For fields in the longitude range 100d < l < 105d, a single pair of 6 MHz bandpasses was used. The narrow channel bandwidth was chosen to minimize the loss of sensitivity over the field of view of the primary beam resulting from bandwidth smearing, while the large frequency separation of the two channels enhances uv coverage. Clean 1024 x 1024 images with 2" pixels were constructed from the calibrated visibility data using the AIPS task MX, resulting in maps with a typical rms of 1 - 2 mJy per beam, allowing for detection of sources down to < 10 mJy.

For use in calculating source surface densities, a survey coverage-sensitivity map with 2' resolution has been constructed; a portion of this map is displayed in Figure 1. In addition to accounting for changes in sensitivity due to vignetting of the primary beam, the map incorporates the higher sensitivity thresholds applicable to ~6% of the fields in which sidelobes from a particularly bright source or poor data quality increases the map rms (e.g., at 19.5 + 0.0 in the portion of the map shown in the figure); these "bad" fields along with their field-center detection thresholds are listed in Table 3.

As is apparent from Figure 1, our sensitivity is far from uniform; the highest sensitivity, achieved on axis, is quoted as 5 times the field rms or 10 mJy, whichever is greater, while the lightest level in the grayscale plot includes regions with sensitivities ranging from 30 to 60 mJy. In particular, the overlap regions at l = 340.25d + n(0.5d), b =+-0.25d (n = 1,2,3...) contain 20 to 40 arcmin2 regions (depending on t) with a threshold > 50 mJy. In addition, at these same values of l with b =+-0.75d there are small unobserved areas within |b|<0.8d, our adopted latitude limit; the exact shape of the missing areas is a function of galactic longitude. In comparing our source list with other catalogues, it is important to remain cognizant of these low sensitivity areas. A histogram of the area surveyed as a function of sensitivity is shown in Figure 2; the solid curve representes the coverage which would have been obtained for this set of pointings if all fields had a 10 mJy central threshold, while the dashed line provides the actual coverage of our survey. Of the 220 square degrees observed, 33% of the area is covered to a peak flux limit of 15 mJy; the survey is 75~o complete to 25 mJy, and 95% complete at a 50 mJy threshold.

Each image was visually inspected for sources which, upon identification, were fit with a two-dimensional Gaussian (with a linear background term subtracted) to determine peak and integrated flux densities, sizes, and source positions (using the AIPS algorithm JMFIT). For sources consisting of two maxima separated by < 15", a simultaneous double Gaussian fit was used. For those extended sources which had obviously non-Gaussian brightness distributions, a flux density was determined by summing the intensity within a polygon enclosing the source (the lack of background subtraction renders these flux densities particularly uncertain); these sources are annotated with a + in the catalogue (see Table 4). For roughly a dozen other sources where the Gaussian fit clearl.y misses surrounding (and presumably related) extended emission, we provide an integrated flux density in the comments column of the catalogue. Finally, in cases where we have detected several adjacent discrete sources which appear to be peaks of an extended region of emission, we highlight the related sources with asterisks.

The antenna spacings in the B-array determine the angular resolution of the images and also limit the sensitivity of the observations to extended structure. The shortest antenna spacing of ~500 wavelengths means that emission on scales larger than ~20"-30" will be invisible or highly attenuated in the images. Thus, some of the catalogued sources represent substructure in a much larger source, and many of the large, bright HII region complexes which dominate lower-resolution maps of the plane have been completely missed. As discussed below and in Paper II, the flux densities of sources larger than 10" in diameter are very ill-determined.

3. The Catalogue

Table 4 contains a list of the 1992 sources detected in our galactic plane survey. For each entry we list a source name based on its galactic coordinates (col. 1), the RA (1950) and Dec (1950) (col. 2 and 3), the peak flux density S_p (col. 4), the integrated flux density S_i (col. 5), and the source diameter (col. 6). The quoted diameters are the mean of the FWHM of the major and minor axes of the sources as determined from the Gaussian fits. The values of S_p and S_i have been corrected for the loss of sensitivity away from the field center (SEE APPENDIX 1). Since the magnitude of this correction as well as a number of other factors which compromise the accurate measurement of source parameters depend on the distance of the source from the field center, we include the off-axis angle in column 7. Notes on a large fraction of the sources are included in column 8. Histograms of the integrated fluxes and measured sizes for all sources are shown in Figures 3 and 4, respectively.

The arrangement of survey field centers resulted in significant overlap in adjacent images. Hence a substantial number of sources were observed two or more times, and this redundancy in the program allowed us to determine the accuracy of the derived source parameters. In Figure 5a we show a histogram of the difference in measured position for all 255 multiply observed sources (MOS). (In the following discussion of survey integrity derived from the MOS sample, we consider only the 215 sources with declinations >~-30d; below this declination limit the beam becomes very elongated, reducing the accuracy of positions, sizes and flux densities. For these southerly sources, error estimates should be doubled.) Over 65% of the positions for sources with sizes < 3" agree to better than 1" or 1/5 of the synthesized beam; for extended sources, the accuracy is only slightly lower. By definition, the MOS all lie at the periphery of the images where the accuracy is lowest; thus, the 90% confidence error circle of 3" derived from this sample is an upper limit to the true uncertainty in source positions. For all MOS, positions quoted in the catalogue are those from the observation in which the source is closest to the field center. We have also checked the accuracy of the catalogue positions as part of a followup study of selected sources using the VLA at 6 cm, 3.5 cm, and 2 cm. In Figure 5b we show the angular offset between the catalogue position and that measured in followup observations, as a function of radial distance of the source from the closest survey field center (the followup observation always has the source at the field center); again, with a few exceptions, a positional accuracy of <~3" is indicated.

The FWHM of the synthesized beam of the VLA in the B-configuration is 3.9" at the zenith for a full-synthesis observation. This degrades by a factor of ~1.3 for snapshot observations, and for sources at the southern declination limit, the north-south elongation reaches 15" (although the A/B configuration was used for most of these fields). In investigating the various components which describe the galactic radio source population, it will be useful to know which of the sources in the catalogue are point-like and which are definitely resolved by our observations. Owing to statistical and systematic uncertainties in measuring the properties of faint sources, our division of sources into "point-like" and "extended" should be a function of source intensity. We find, however, that independent of flux density, > 95% of all sources with measured sizes > 3" have S_i/S_p > 1.3, whereas fewer than 5% of all sources smaller than this have a flux ratio exceeding this value (Figure 6a). Since we will frequently only consider sources with fluxes > 20 mJy where the dividing line is even more marked, we adopt hereafter a division between point and extended sources of 3" (Figure 6b).

Finally, we may use the MOS to examine the quality of our flux determinations. In Figure 7, we plot the fractional flux density differences (S_close - S_far)/S_close as a function of off-axis angle, where S_close is the integrated flux density measured for the observation in which the source is closer to the field center. For the unresolved sources, a typical fractional flux density error of approximately +-30% appears to be appropriate. The extended sources, however, clearly represent a more serious problem; this is discussed in some detail in Paper II.

4. Additional Information on Catalogued Sources

In the final column of Table 4 we include a number of notes regarding the catalogued sources; a translation of the symbols used is provided in Table 5. These consist of annotations resulting from special circumstances related to the derivation of source parameters (e.g., integrated flux densities for source complexes), as well as information culled from previous galactic plane surveys (Table 1), from the IRAS catalogue, from other catalogues of astronomical objects, and from followup observations we have conducted with the VLA and at Lick Observatory. We describe briefly the genesis of the catalogue notes, deferring to future papers a detailed discussion of their implications for the source content of our survey.

In Table 6 we list the source catalogues with which we have compared our galactic plane survey sources; the catalogues in the first half of the Table exist in machine-readable form and we have performed a direct comparison with Table 4, adopting a 3" error circle radius for our sources and the quoted uncertainties for the other catalogues. For the IRAS point source catalogue, a more sophisticated matching algorithm which ascribes a probability of true association to each potential match has been developed and is described in detail in Paper III; we mark in Table 4 all objects whose chance association probability is < 25%, although more than three quarters of these sources have a chance rate of < 5%. The expected false coincidence rate in all comparisons has been determined by repeating the matching algorithm with all radio source positions offset by 10' in each of the four cardinal directions and averaging the numbers of false hits obtained. Lists of stellar counterparts, planetary nebulae, and X-ray source coincidences are compiled in Table 7.

The catalogues of radio sources in the lower half of Table 6 are not readily available in machine-readable form and, given the lower spatial resolution of the observations contained therein, are not directly comparable to individual sources in our catalogue. To search for potential associations (e.g., instances where we have detected the highest surface brightness spot(s) of an extended supernova remnant or HII region complex), we have constructed maps of our source positions scaled to the contour maps presented in each of the first three references. When one (or more) of our source(s) falls within the contours of a catalogued object, the association is noted. The recombination line survey source lists are drawn from these same catalogues, and if at least one line has been detected, an annotation is included. Sources falling within the contours of the known supernova remnants within our survey area are also noted. The large factor by which we underestimate the fluxes of SNRs and the fact that most of the remnants are not detected at all is a reminder of our insensitivity to extended emission. Thus, no spectral information is derivable from a comparison of our 20 cm flux densities and the flux densities at higher frequencies listed in the single-dish catalogues. The Texas interferometer survey does, however, have a resolution comparable to our observations and a comparison of the two catalogues can provide useful spectral information as we discuss in Paper II.

Based on such radio spectra, on the coincidence of a small-diameter (< 3") radio source with an IRAS point source, and on a variety of other criteria, we have undertaken followup observations of 77 catalogue sources with the VLA at 20 cm, 6 cm, 3.5 cm and 2 cm wavelengths. The implications for source identifications are presented in Paper II; here we include in Table 8 the flux densities derived from these data for 44 of the sources with followup observations. Data on the remaining objects, selected to search for young supernova remnants, are given in Paper II. Finally, we have undertaken optical imaging and spectroscopic followup observations using the 1-m and 3-m telescopes of the Lick Observatory. Details of these observations will be presented in a forthcoming paper (Becker et al. 1990b); the existence of optical observations is indicated by an LO in the Comments column. The information in Table 4 is available in machine readable form and will be supplied to any interested users on request. An analysis of the survey will provide, among other things, a complete flux-limited sample of compact HII regions, a limit on the number of young SNR in the galactic plane, a significant number of new planetary nebulae and radio stars, and most likely, several unexpected discoveries. When coupled with the results of ongoing VLA plane surveys we are conducting at 6 cm and 90 cm, these data provide a qualitatively new view of the radio source population of the Milky Way.

Appendix 1

As with all such telescope systems, the VLA antennas suffer vignetting- the loss of sensitivity as one moves away from the optical axis. The VLA data reduction system contains a routine PBCOR (primary beam correction) to correct measured flux densities for this effect. The routine calculates the correction from the polynomial
Corr = a1 + a2 x + a3 x^2 + a4 x^3 + a5 x^4 (A1)
where x is the square of the angular distance from the pointing position in arcminutes times the frequency in GHz. The parameters a are
a1 = 0.9920378
a2 = 0.9956885 x 10^-3
a3 = 0.3814573 x 10^-5
a4 = -0.5311695 x 10^-8
a5 = 0.3980963 x 10^-11.
In figure A1a, we plot the ratios of the corrected peak flux densities for MOS as a function of off-axis angle using the mean frequency of our two-band observations, 1526 MHz. It is clear that the mean ratio is > 1; i.e., that we are undercorrecting the flux densities for sources far from the field center. A simple fix to this problem is to change the effective frequency of the observations. We have determined the correct choice of frequency by calculating the mean and rms of the peak flux density for 166 pairs of MOS point sources within 20' of the field center at 25 MHz intervals from 1425 MHz to 1750 MHz. The mean is closest to 1.00 and the rms is minimized at an effective frequency of 1700 MHz. Figure A1b shows the result of using this frequency which we have adopted in correcting the values in table 4. For the 19 sources in the catalogue with off-axis distances > 20' the difference in the correction between the nominal and adopted frequencies is ~ 100%; for the vast majority of the catalogued objects with distances < 12', the discrepancy is < 15%, well within the quoted flux density uncertainty.

REFERENCES

Altenhoff, W.J., Downes, D., Pauls, T., and Schraml, J. 1978, A&AS 35, 23
Altenhoff, W.J., Downes, D., Gaad, L., Maxwell, A., and Rinehart, R. 1970, A&AS 1, 319.
Becker, R.H., White, R.L., McLean, B.J., Helfand, D.J. & Zoonematkermani, S. 1990, ApJ 358, 485 (Paper II)
Becker, R.H., White, R.L. and Helfand, D.J. 1990b (in preparation)
Caswell, J.L. and Haynes, R.F. 1987, Astron. Astrophys., 171, 261.
Day, G.A., Caswell, J.L., and Cooke, D.J. 1972, Aust. J. Phys. Suppl., 25, 1.
Douglas, J.N., Bash, F.N., Torrence, G.W. and Wolfe, C. 1980, "The Texas Survey: Preliminary +18 deg Strip," preprint of Univ. of Texas at Austin.
Fich, M. 1986, Astron. J., 92, 787.
Garwood, R.W., Perley, R.A., Dickey, J.M. and Murray, M.A. 1988, A.J., 96, 1655.
Green, A.J. 1974, Astron. Astrophys. Suppl., 18, 267.
Green, D.A. 1987, Astron. Astrophys. Suppl., 78, 277.
Handa, T., Sofue, Y., Nakai, N., Harabayashi, H., and Inoue, M. 1987, PASJ 39, 709.
Haynes, R.F., Caswell, J.L. & Simmons, L.W.J. 1978, AuJPA 48, 1.
Higgs, L. 1989, J. Royal Astr. Soc. Canada, 83, 105.
Joncas, G. and Higgs, L. 1990, A&AS 82, 113; erratum vol. 83, 392
Kallas, E., and Reich, W. 1980, Astron. Astrophys. Suppl., 42, 227.
Lockman, F.J., 1989, ApJS 71, 469.
Reich, W., Furst, E., Steffer, P., Reif, K. & Haslam, G.G.T. 1984, A&AS 58, 197.
White, R.L., Becker, R.H., and Helfand, D.J. 1990, (Paper III - in preparation).

Table 1. GALACTIC PLANE RADIO SURVEYS

* Actual limits are higher owing to source confusion in the plane 
----+----1----+----2----+----3----+----4----+----5----+----6----+----7----+----8
Frequency Telescope    Resolution S_min      Coverage      No. of   Reference
(MHz)                   (arcmin)  (Jy)      l/deg   b/deg  Sources
----+----1----+----2----+----3----+----4----+----5----+----6----+----7----+----8
  408 Molongo Cross         3.   ~1.     195 - 55   +-3.0   ...    Green 1974
  408 DRAO Interferometer   3.5   .003*  65 - 180   +-3   in prog. Higgs 1989; Green 1989
 1400 Greenbank 400 ft     10.    1.     12 - 55    +-4.0   356    Altenhoff et al. 1970
 1400 Effelsberg 100 m      9.     .3    93- 162    +-4.0   236    Kallas and Reich 1980
 1400 DRAO Interferometer   1.    .001*  sampled          in prog. Jonces and Higgs 1990
 2700 Greenbank 140 ft     11.    1.    345 - 75    +-2.0   356    Altenhoff et al. 1970
 2700 Parkes 64 m           8.2    .2   190 - 61    +-2.0  ~890    Day et al. 1972
 2700 Effelsberg 100 m      4.3   ~.1   357.4- 76   +-1.5  1212    Reich et al. 1984
 4875 Effelsberg 100 m      2.6   ~.4   357.5 - 60  +-1.   1186    Altenhoff et al. 1978
 5000 Ft. Davis 85 ft      10.8   4.    335 - 55    +-3.0   356    Altenhoff et aL 1970
 5000 Parkes 64 m           4.4   ~.5   190 - 40    +-2.0   915    Haynes et al. 1978
10050 Nobeyama 45 m         2.7   ~.5   356 - 56    +-1.5   144    Handa et al.