J/A+A/609/A37 875 nearby galaxies multiwavelength photometry (Clark+, 2018)
DustPedia: Multiwavelength photometry and imagery of 875 nearby galaxies in
42 ultraviolet-microwave bands.
Clark C.J.R., Verstocken S., Bianchi S., Fritz J., Viaene S., Smith M.W.L.,
Baes M., Casasola V., Cassara L.P., Davies J.I., De Looze I., De Vis P.,
Evans R., Galametz M., Jones A.P., Lianou S., Madden S., Mosenkov A.V.,
Xilouris M.
<Astron. Astrophys. 609, A37 (2018)>
=2018A&A...609A..37C 2018A&A...609A..37C (SIMBAD/NED BibCode)
ADC_Keywords: Galaxies, nearby ; Galaxies, photometry
Keywords: galaxies: photometry - galaxies: general - techniques: photometric -
dust, extinction - surveys - catalogues
Abstract:
The DustPedia project is capitalising on the legacy of the Herschel
Space Observatory, using cutting-edge modelling techniques to study
dust in the 875 DustPedia galaxies - representing the vast majority of
extended galaxies within 3000km/s that were observed by Herschel.
This work requires a database of multiwavelength imagery and
photometry that greatly exceeds the scope (in terms of wavelength
coverage and number of galaxies) of any previous local-Universe
survey. We constructed a database containing our own custom Herschel
reductions, along with standardised archival observations from GALEX,
SDSS, DSS, 2MASS, WISE, Spitzer, and Planck. Using these data, we
performed consistent aperture-matched photometry, which we combined
with external supplementary photometry from IRAS and Planck. We
present our multiwavelength photometry across 40 UV-microwave bands
for the 875 DustPedia galaxies. Our aperture-matched photometry,
combined with the external supplementary photometry, represents a
total of 21,857 photometric measurements. A typical DustPedia galaxy
has multiwavelength photometry spanning 25 bands. To carry out our
photometry we developed the Comprehensive & Adaptable Aperture
Photometry Routine (CAAPR). CAAPR is designed to produce consistent
photometry for the enormous range of galaxy and observation types in
our data. In particular, CAAPR is able to determine robust
cross-compatible uncertainties, thanks to a novel method for reliably
extrapolating the aperture noise for observations that cover a very
limited amount of background.
Description:
These tables contain multiwavelength photometry for the 875 DustPedia
galaxies, spanning 40 photometric bands. Aperture-matched photometry,
performed using the CAAPR pipeline, is provided for 27 bands (from
GALEX, SDSS, 2MASS, WISE, Spitzer, and Herschel). Ancillary photometry
from IRAS SCANPI and Planck CCS2. Images available in FITS format from
the DustPedia database (http://dustpedia.astro.noa.gr).
File Summary:
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FileName Lrecl Records Explanations
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ReadMe 80 . This file
sample.dat 130 875 Galaxy sample
apphot.dat 693 875 Aperture-matched photometry for 27 bands
(GALEX, SDSS, 2MASS, WISE, Spitzer, and Herschel)
irasphot.dat 124 875 Ancillary photometry from IRAS SCANPI
plnkphot.dat 224 875 Ancillary photometry from Planck CCS2
fits/* . 4 All tables in fits format
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See also:
II/312 : GALEX-DR5 (GR5) sources from AIS and MIS (Bianchi+ 2011)
V/147 : The SDSS Photometric Catalogue, Release 12 (Alam+, 2015)
II/246 : 2MASS All-Sky Catalog of Point Sources (Cutri+ 2003)
II/311 : WISE All-Sky Data Release (Cutri+ 2012)
II/125 : IRAS catalogue of Point Sources, Version 2.0 (IPAC 1986)
J/A+A/594/A26 : Second Planck Catalogue of Compact Sources (PCCS2)
(Planck+, 2016)
http://dustpedia.astro.noa.gr : DustPedia Home Page
Byte-by-byte Description of file: sample.dat
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Bytes Format Units Label Explanations
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1- 23 A23 --- Name Name (name)
25- 33 F9.5 deg RAdeg Right ascension (J2000) (ra)
35- 43 F9.5 deg DEdeg Declination (J2000) (dec)
45- 48 F4.1 --- MType ? Morphological type (morph_type)
50- 53 A4 --- MClass Morphological class (morph_class)
55- 61 F7.4 arcmin D25 Major axis isophote at which optical surface
brightness falls beneath 25mag/arcsec2 (d25)
63- 71 F9.6 deg Incl Inclination (inclination)
73- 76 I4 km/s HV ?=- NED heliocentric velocity (nedvhelio) (1)
78- 82 I5 km/s HVcorr ?=- NED corrected heliocentric velocity
(nedvcorr) (1)
84- 91 F8.5 Mpc Distcorr ?=- NED corrected distance
(neddistz_corr) (1)
93- 97 F5.2 Mpc Dist0 ?=- NED redshift-independent distance
(neddist0) (1)
99-103 I5 km/s HVH ?=- HYPERLEDA heliocentric velocity
(hyperledavhelio) (2)
105-112 F8.5 Mpc DistH ?=- HYPERLEDA distance
(hyperledadistz_helio) (2)
114-121 F8.5 Mpc Dist0H ?=- HYPERLEDA redshift-independent distance
(hyperledadist0) (2)
123-130 F8.5 Mpc Dist Best distance (dist_best) (3)
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Note (1): Quantities from NED (https://ned.ipac.caltech.edu/)
Note (2): Quantities from HyperLEDA (http://leda.univ-lyon1.fr/)
Note (3): Our preferred distance estimates are the redshift-independent
distances provided by the HyperLEDA database, as these have been homogenised
to account for methodological differences between references. For galaxies
without redshift-independent HyperLEDA distances, our next preferred values
are the redshift-independent distances provided by the Nasa/ipac Extragalactic
Database (NED); whilst these are not homogenised like the HyperLEDA values, we
take the quoted average value for each galaxy to minimise bias.
If neither HyperLEDA nor NED redshift-independent distances are available for
a source, we use the flow-corrected redshift-derived values provided by NED
these distances were calculated assuming a Hubble constant of H0=73.24km/s/Mpc
(Riess et al. 2016, Cat. J/ApJ/826/56), and have been corrected for bulk
deviation from Hubble flow arising from the influence of the Virgo Cluster,
the Great Attractor, and the Shapley Supercluster
(Mould et al. 2000ApJ...529..786M 2000ApJ...529..786M).
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Byte-by-byte Description of file: apphot.dat
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Bytes Format Units Label Explanations
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1- 23 A23 --- Name Name (name)
25- 33 F9.5 deg RAdeg Right ascension (J2000) (ra)
35- 43 F9.5 deg DEdeg Declination (J2000) (dec)
45- 53 F9.4 arcsec amaj Semi-major axis (semimaj_arcsec)
55- 61 F7.5 --- b/a Axial ratio (axial_ratio)
63- 69 F7.3 deg PA [] Position angle (pos_angle)
71 A1 --- Flag [Cc] Global flag (global_flag) (G1)
73- 81 E9.3 Jy FFUV ? GALEX_FUV flux (GALEX_FUV) (1)
83- 91 E9.3 Jy e_FFUV ? rms uncertainty on FFUV (GALEXFUVerr) (G2)
93 A1 --- f_FFUV [ACNacn ] Flag on FFUV (GALEXFUVflag) (G1)
95-103 E9.3 Jy FNUV ? GALEX_NUV flux (GALEX_NUV) (1)
105-113 E9.3 Jy e_FNUV ? rms uncertainty on FNUV (GALEXNUVerr) (G2)
115 A1 --- f_FNUV [ACNacn ] Flag on FNUV (GALEXNUVflag) (G1)
117-125 E9.3 Jy Fu ? SDSS u flux (SDSS_u) (1)
127-135 E9.3 Jy e_Fu ? rms uncertainty on Fu (SDSSuerr) (G2)
137-138 A2 --- f_Fu [ACNacn ] Flag on Fu (SDSSuflag) (G1)
140-148 E9.3 Jy Fg ? SDSS g flux (SDSS_g) (1)
150-158 E9.3 Jy e_Fg ? rms uncertainty on Fg (SDSSgerr) (G2)
160-161 A2 --- f_Fg [ACNacn ] Flag on Fg (SDSSgflag) (G1)
163-171 E9.3 Jy Fr ? SDSS r flux (SDSS_r) (1)
173-181 E9.3 Jy e_Fr ? rms uncertainty on (SDSSrerr) (G2)
183-184 A2 --- f_Fr [ACNacn ] Flag on Fr (SDSSrflag) (G1)
186-194 E9.3 Jy Fi ? SDSS i flux (SDSS_i) (1)
196-204 E9.3 Jy e_Fi ? rms uncertainty on Fi (SDSSierr) (G2)
206-207 A2 --- f_Fi [ACNacn ] Flag on Fi (SDSSiflag) (G1)
209-217 E9.3 Jy Fz ? SDSS z flux (SDSS_z) (1)
219-227 E9.3 Jy e_Fz ? rms uncertainty on Fz (SDSSzerr) (G2)
229-230 A2 --- f_Fz [ACNacn ] Flag on (SDSSzflag) (G1)
232-240 E9.3 Jy FJ 2MASS J flux (2MASS_J) (1)
242-250 E9.3 Jy e_FJ rms uncertainty on FJ (2MASSJerr) (G2)
252 A1 --- f_FJ [ACac ] Flag on FJ (2MASSJflag) (G1)
254-262 E9.3 Jy FH 2MASS H flux (2MASS_H) (1)
264-272 E9.3 Jy e_FH rms uncertainty on FH (2MASSHerr) (G2)
274 A1 --- f_FH [ACac ] Flag on FKs (2MASSHflag) (G1)
276-284 E9.3 Jy FKs 2MASS Ks flux (2MASS_Ks) (1)
286-294 E9.3 Jy e_FKs rms uncertainty on FKs (2MASSKserr) (G2)
296 A1 --- f_FKs [ACac ] Flag on FKs (2MASSKsflag) (G1)
298-306 E9.3 Jy F3.4 WISE 3.4um flux (WISE_3.4) (1)
308-316 E9.3 Jy e_F3.4 rms uncertainty on F3.4 (WISE3.4err) (G2)
318-319 A2 --- f_F3.4 [ACac ] Flag on F3.4 (WISE3.4flag) (G1)
321-329 E9.3 Jy F4.6 WISE 4.6um flux (WISE_4.6) (1)
331-339 E9.3 Jy e_F4.6 rms uncertainty on F4.6(WISE4.6err) (G2)
341-342 A2 --- f_F4.6 [ACac ] Flag on F4.6 (WISE4.6flag) (G1)
344-352 E9.3 Jy F12 WISE 12um flux (WISE_12) (1)
354-362 E9.3 Jy e_F12 rms uncertainty on F12 (WISE12err) (G2)
364-365 A2 --- f_F12 [ACacn ] Flag on F12 (WISE12flag) (G1)
367-375 E9.3 Jy F22 WISE 22um flux (WISE_22) (1)
377-385 E9.3 Jy e_F22 rms uncertainty on F22 (WISE22err) (G2)
387-388 A2 --- f_F22 [ACacn ] Flag on F22 (WISE22flag) (G1)
390-398 E9.3 Jy F3.6 ? Spitzer 3.6um flux (Spitzer_3.6) (1)
400-408 E9.3 Jy e_F3.6 ? rms uncertainty on F3.6 (Spitzer3.6err) (G2)
410-412 A3 --- f_F3.6 [ACNacn ] Flag on F3.6 (Spitzer3.6flag) (G1)
414-422 E9.3 Jy F4.5 ? Spitzer 4.5um flux (Spitzer_4.5) (1)
424-432 E9.3 Jy e_F4.5 ? rms uncertainty on F4.5 (Spitzer4.5err) (G2)
434-436 A3 --- f_F4.5 [ACNacn ] Flag on F4.5 (Spitzer4.5flag) (G1)
438-446 E9.3 Jy F5.8 ? Spitzer 5.8um flux (Spitzer_5.8) (1)
448-456 E9.3 Jy e_F5.8 ? rms uncertainty on F5.8 (Spitzer5.8err) (G2)
458-460 A3 --- f_F5.8 [ACNacn ] Flag on F5.8 (Spitzer5.8flag) (G1)
462-470 E9.3 Jy F8.0 ? Spitzer 8.0um flux (Spitzer_8.0) (1)
472-480 E9.3 Jy e_F8.0 ? rms uncertainty on F8.0 (Spitzer8.0err) (G2)
482-484 A3 --- f_F8.0 [ACNacn ] Flag on F8.0 (Spitzer8.0flag) (G1)
486-494 E9.3 Jy F24 ? Spitzer 24um flux (Spitzer_24) (1)
496-504 E9.3 Jy e_F24 ? rms uncertainty on F24 (Spitzer24err) (G2)
506-508 A3 --- f_F24 [ACNacn ] Flag on F24 (Spitzer24flag) (G1)
510-518 E9.3 Jy F70 ? Spitzer 70um flux (Spitzer_70) (1)
520-528 E9.3 Jy e_F70 []? rms uncertainty on F70 (Spitzer70err) (G2)
530-532 A3 --- f_F70 [ACNacn ] Flag on F70 (Spitzer70flag) (G1)
534-542 E9.3 Jy F160 ? Spitzer 160um flux (Spitzer_160) (1)
544-552 E9.3 Jy e_F160 []? rms uncertainty on F160
(Spitzer160err) (G2)
554-555 A2 --- f_F160 [ACNacn ] Flag on F160 (Spitzer160flag) (G1)
557-565 E9.3 Jy F70P ? PACS 70um (PACS_70) (1)
567-575 E9.3 Jy e_F70P []? rms uncertainty on F70P (PACS70err) (G2)
577-578 A2 --- f_F70P [ACNacn ] Flag on F70P (PACS70flag) (G1)
580-588 E9.3 Jy F100P ? PACS 100um (PACS_100) (1)
590-598 E9.3 Jy e_F100P []? rms uncertainty on F100P (PACS100err) (G2)
600-601 A2 --- f_F100P [ACNacn ] Flag on F100P (PACS100flag) (G1)
603-611 E9.3 Jy F160P ? PACS 160um (PACS_160) (1)
613-621 E9.3 Jy e_F160P []? rms uncertainty on F160P (PACS160err) (G2)
623-624 A2 --- f_F160P [ACNacn ] Flag on F160P (PACS160flag) (G1)
626-634 E9.3 Jy F250 ? SPIRE 250um (SPIRE_250) (1)
636-644 E9.3 Jy e_F250 ? rms uncertainty on F250 (SPIRE250err) (G2)
646-647 A2 --- f_F250 [ACNacn ] Flag on F250 (SPIRE250flag) (G1)
649-657 E9.3 Jy F350 ? SPIRE 230um (SPIRE_350) (1)
659-667 E9.3 Jy e_F350 []? rms uncertainty on F350 (SPIRE350err) (G2)
669-670 A2 --- f_F350 [ACNacn ] Flag on F350 (SPIRE350flag) (G1)
672-680 E9.3 Jy F500 ? SPIRE 500um (SPIRE_500) (1)
682-690 E9.3 Jy e_F500 []? rms uncertainty on F500 (SPIRE500err) (G2)
692-693 A2 --- f_F500 [ACNacn ] Flag on F500 (SPIRE500flag) (G1)
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Note (1): To account for the wide range of resolutions in the data we employ,
we convolved our photometric apertures with the beam in each band, in order
to render the photometry aperture-matched.
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Byte-by-byte Description of file: irasphot.dat
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Bytes Format Units Label Explanations
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1- 23 A23 --- Name Name (name)
25- 34 F10.6 Jy F12 ? IRAS 12um flux (IRAS_12)
36- 44 F9.6 Jy e_F12 ? rms uncertainty on F12 (IRAS12err) (G2)
46- 47 A2 --- f_F12 [ecC ] Flag on F12 (IRAS12flag) (G1)
49- 59 F11.6 Jy F25 ? IRAS 25um flux (IRAS_25)
61- 69 F9.6 Jy e_F25 ? rms uncertainty on F25 (IRAS25err) (G2)
71- 72 A2 --- f_F25 [ecC ] Flag on F25 (IRAS25flag) (G1)
74- 84 F11.6 Jy F60 ? IRAS 60um flux (IRAS_60)
86- 95 F10.6 Jy e_F60 ? rms uncertainty on F60 (IRAS60err) (G2)
97- 98 A2 --- f_F60 [ecC ] Flag on F60 (IRAS60flag) (G1)
100-110 F11.6 Jy F100 ? IRAS 100um flux (IRAS_100)
112-121 F10.6 Jy e_F100 ? rms uncertainty on F100 (IRAS100err) (G2)
123-124 A2 --- f_F100 [ecC] Flag on F100 (IRAS100flag) (G1)
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Byte-by-byte Description of file: plnkphot.dat
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Bytes Format Units Label Explanations
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1- 23 A23 --- Name Name (name)
25- 33 E9.3 Jy F350 ? Planck 350um flux (Planck_350)
35- 43 E9.3 Jy e_F350 ? rms uncertainty on F350 (Planck350err) (G2)
45- 46 A2 --- f_F350 [ecC ] Flag on F350 (Planck350flag) (G1)
48- 56 E9.3 Jy F550 ? Planck 550um flux (Planck_550)
58- 66 E9.3 Jy e_F550 ? rms uncertainty on F550 (Planck550err) (G2)
68- 69 A2 --- f_F550 [ecC ] Flag on F550 (Planck550flag) (G1)
71- 79 E9.3 Jy F850 ? Planck 850um flux (Planck_850)
81- 89 E9.3 Jy e_F850 ? rms uncertainty on F850 (Planck850err) (G2)
91- 92 A2 --- f_F850 [ecC ] Flag on F850 (Planck850flag) (G1)
94-102 E9.3 Jy F1380 ? Planck 1380um flux (Planck_1380)
104-112 E9.3 Jy e_F1380 ? rms uncertainty on F1380 (Planck1380err) (G2)
114 A1 --- f_F1380 [e] Flag on F1380 (Planck1380flag) (G1)
116-124 E9.3 Jy F2100 ? Planck 2100um flux (Planck_2100)
126-134 E9.3 Jy e_F2100 ? rms uncertainty on F2100 (Planck2100err) (G2)
136 A1 --- f_F2100 [e] Flag on F2100 (Planck2100flag) (G1)
138-146 E9.3 Jy F3000 ? Planck 3000um flux (Planck_3000)
148-156 E9.3 Jy e_F3000 ? rms uncertainty on F3000 (Planck3000err) (G2)
158 A1 --- f_F3000 [e] Planck 3000um flux (Planck3000flag) (G1)
160-168 E9.3 Jy F4260 ? Planck 4260um (Planck_4260)
170-178 E9.3 Jy e_F4260 ? rms uncertainty on F4260 (Planck4260err) (G2)
180 A1 --- f_F4260 [0] Flag on F4260 (Planck4260flag)
182-190 E9.3 Jy F6810 ? Planck 6810um flux (Planck_6810)
192-200 E9.3 Jy e_F6810 ? rms uncertainty on F6810 (Planck6810err) (G2)
202 A1 --- f_F6810 [0] Flag on F6810 (Planck6810flag)
204-212 E9.3 Jy F10600 ? Planck 10600um flux (Planck_10600)
214-222 E9.3 Jy e_F10600 ? rms uncertainty on F10600
(Planck10600err) (G2)
224 A1 --- f_F10600 [0] Flag on F10600 (Planck10600flag)
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Global notes:
Note (G1): Flags (full explanations in Sections 4 and 5 of paper) as follows:
A = Artefact flag. This indicates that some sort of map artefact is present
in the region of the target source, as determined by visual inspection.
Examples of this include poor mosaicing in the archival data, satellite
trails, or evidence of saturation in bright pixels, upper case.
a = Artefact flag. This indicates that some sort of map artefact is present
in the region of the target source, as determined by visual inspection.
Examples of this include poor mosaicing in the archival data, satellite
trails, or evidence of saturation in bright pixels, lower case.
C = Contamination flag. This indicates contamination of the photometry due to
a nearby source, as determined by visual inspection. Examples of this
include foreground stars that were not fully removed, or other galaxies
close to the target source, upper case.
c = Contamination flag. This indicates contamination of the photometry due to
a nearby source, as determined by visual inspection. Examples of this
include foreground stars that were not fully removed, or other galaxies
close to the target source, lower case.
N = Null-coverage flag. This flag is automatically assigned where necessary.
This indicates that the observation didn't provide full coverage of the
area of the source, limiting CAAPR's ability to suitably measure the
source flux and/or background. If more than 20% of the pixels in the
master aperture and/or more than 60% of the pixels in the background
annulus are found to be NaN, a major flag is raised. Instruments for
which small maps are common (such as Spitzer and PACS) are particularly
likely to have fluxes with this flag.
n = Null-coverage flag. This flag is automatically assigned where necessary.
This indicates that the observation didn't provide full coverage of the
area of the source, limiting CAAPR's ability to suitably measure the
source flux and/or background. If more than 5% of the pixels in the
master aperture and/or more than 20% of the pixels in the background
annulus are found to be NaN - 'Not a Number' - then a minor flag is
raised.
E = Excluded extended emission flag. This flag is only used with our
supplementary photometry (as described in Section 5), and is not
assigned to any of our aperture-matched CAAPR fluxes. It indicates that
the target is sufficiently extended that there is a risk some of its
emission will have been excluded from the measurement in question,
which would lead to the flux being an under-estimate, upper case.
e = Excluded extended emission flag. This flag is only used with our
supplementary photometry (as described in Section 5), and is not
assigned to any of our aperture-matched CAAPR fluxes. It indicates that
the target is sufficiently extended that there is a risk some of its
emission will have been excluded from the measurement in question,
which would lead to the flux being an under-estimate, lower case.
Note (G2): Quoted uncertainties incorporate instrumental calibration
uncertainties.
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Acknowledgements:
Christopher Clark, cjrc88(at)gmail.com
(End) Patricia Vannier CDS 17-Aug-2017