论文信息 - Deep SOAR follow-up photometry of two Milky Way outer-halo companions discovered with Dark Energy Survey - 字舞流文

Deep SOAR follow-up photometry of two Milky Way outer-halo companions discovered with Dark Energy Survey

We report the discovery of a new star cluster, DES 3, in the constellation of Indus, and deeper observations of the previously identified satellite DES J0222.7−5217 (Eridanus III). DES 3 was detected as a stellar overdensity in first-year Dark Energy Survey data, and confirmed with deeper photometry from the 4.1-m Southern Astrophysical Research (SOAR) telescope. The new system was detected with a relatively high significance and appears in the DES images as a compact concentration of faint blue point sources. We determine that DES 3 is located at a heliocentric distance of ≃76.2 kpc and it is dominated by an old (≃9.8 Gyr) and metal-poor ([Fe/H] ≃ −1.84) population. While the age and metallicity values of DES 3 are comparable to typical globular clusters (objects with a high stellar density, stellar mass of ∼10^5 M⊙ and luminosity M_V ∼ −7.3), its half-light radius (r_h ∼ 6.87 pc) and luminosity (M_V ∼ −1.7) are more indicative of faint star cluster. Based on the angular size, DES 3, with a value of r_h ∼ 0.”31, is among the smallest faint star clusters known to date. Furthermore, using deeper imaging of DES J0222.7−5217 taken with the SOAR telescope, we update structural parameters and perform the first isochrone modelling. Our analysis yields the first age (≃12.6 Gyr) and metallicity ([Fe/H] ≃ −2.01) estimates for this object. The half-light radius (r_h ≃ 11.24 pc) and luminosity (M_V ≃ −2.4) of DES J0222.7−5217 suggest that it is likely a faint star cluster. The discovery of DES 3 indicates that the census of stellar systems in the Milky Way is still far from complete, and demonstrates the power of modern wide-field imaging surveys to improve our knowledge of the Galaxy’s satellite population.

R. Nichol | D. Gerdes | F. Abdalla | A. Rosell | L. Costa | K. Honscheid | M. Maia | B. Santiago | F. Sobreira | R. Kron | M. Kind | R. Gruendl | J. Annis | S. Allam | I. Sevilla-Noarbe | K. Bechtol | E. Bertin | D. Brooks | J. Carretero | M. Crocce | C. Davis | P. Doel | A. Drlica-Wagner | T. Eifler | B. Flaugher | D. Gruen | G. Gutiérrez | D. James | K. Kuehn | J. Marshall | R. Miquel | A. Plazas | V. Scarpine | R. Schindler | M. Smith | E. Suchyta | G. Tarlé | A. Walker | E. Balbinot | A. F. Neto | M. Soares-Santos | J. Garc'ia-Bellido | A. Benoit-Lévy | E. Sánchez | D. Thomas | N. Kuropatkin | A. Pace | A. Pieres | A. Queiroz | E. Luque | M. C. Kind | A. C. Rosell | M. Ponte | J. Marshall | A. F. Neto | M. D. Ponte

[1] J.Lee,et al. THE DARK ENERGY CAMERA , 2004, The Dark Energy Survey.

[2] Mauricio Solar,et al. Astronomical data analysis software and systems , 2018, Astron. Comput..

[3] B. Yanny,et al. Dark Energy Survey Year 1 Results: The Photometric Data Set for Cosmology , 2017, 1708.01531.

[4] R. Lupton,et al. Searches for New Milky Way Satellites from the First Two Years of Data of the Subaru/Hyper Suprime-Cam Survey: Discovery of Cetus~III , 2017, 1704.05977.

[5] K. Bechtol,et al. The predicted luminous satellite populations around SMC and LMC-mass galaxies - A missing satellite problem around the LMC? , 2017, 1703.05321.

[6] B. Chaboyer,et al. Absolute Ages and Distances of 22 GCs Using Monte Carlo Main-sequence Fitting , 2017, 1703.01915.

[7] Sergey E. Koposov,et al. Gaia 1 and 2. A pair of new Galactic star clusters , 2017, Monthly Notices of the Royal Astronomical Society.

[8] J. Frieman,et al. Nearest Neighbor: The Low-mass Milky Way Satellite Tucana III , 2016, 1610.05301.

[9] C. Frenk,et al. Identifying true satellites of the Magellanic Clouds. , 2016, 1605.03574.

[10] J. Frieman,et al. Farthest Neighbor: The Distant Milky Way Satellite Eridanus II , 2016, 1611.05052.

[11] R. Lupton,et al. A NEW MILKY WAY SATELLITE DISCOVERED IN THE SUBARU/HYPER SUPRIME-CAM SURVEY , 2016, 1609.04346.

[12] D. Nidever,et al. AN ULTRA-FAINT GALAXY CANDIDATE DISCOVERED IN EARLY DATA FROM THE MAGELLANIC SATELLITES SURVEY , 2016, 1609.02148.

[13] A. Milone,et al. PORTRAIT OF A DARK HORSE: A PHOTOMETRIC AND SPECTROSCOPIC STUDY OF THE ULTRA-FAINT MILKY WAY SATELLITE PEGASUS III , 2016, 1608.04934.

[14] D. Gerdes,et al. The Dark Energy Survey view of the Sagittarius stream: discovery of two faint stellar system candidates , 2016, 1608.04033.

[15] Sergey E. Koposov,et al. At the survey limits: discovery of the Aquarius 2 dwarf galaxy in the VST ATLAS and the SDSS data , 2016, 1605.05338.

[16] V. Belokurov,et al. A Magellanic origin of the DES dwarfs , 2016, 1603.04420.

[17] Sergey E. Koposov,et al. The feeble giant. Discovery of a large and diffuse Milky Way dwarf galaxy in the constellation of Crater , 2016, 1601.07178.

[18] Sergey E. Koposov,et al. MAGELLAN/M2FS SPECTROSCOPY OF TUCANA 2 AND GRUS 1 , 2015, The Astrophysical Journal.

[19] R. Nichol,et al. Digging deeper into the Southern skies: a compact Milky Way companion discovered in first-year Dark Energy Survey data , 2015, 1508.02381.

[20] A. Milone,et al. KIM 3: AN ULTRA-FAINT STAR CLUSTER IN THE CONSTELLATION OF CENTAURUS , 2015, 1512.03530.

[21] R. Nichol,et al. Physical properties of star clusters in the outer LMC as observed by the DES , 2015, 1512.01032.

[22] B. Yanny,et al. EIGHT ULTRA-FAINT GALAXY CANDIDATES DISCOVERED IN YEAR TWO OF THE DARK ENERGY SURVEY , 2015, 1508.03622.

[23] John L. Tonry,et al. SAGITTARIUS II, DRACO II AND LAEVENS 3: THREE NEW MILKY WAY SATELLITES DISCOVERED IN THE PAN-STARRS 1 3π SURVEY , 2015, 1507.07564.

[24] H. Jerjen,et al. HOROLOGIUM II: A SECOND ULTRA-FAINT MILKY WAY SATELLITE IN THE HOROLOGIUM CONSTELLATION , 2015, 1505.04948.

[25] Sergey E. Koposov,et al. KINEMATICS AND CHEMISTRY OF RECENTLY DISCOVERED RETICULUM 2 AND HOROLOGIUM 1 DWARF GALAXIES , 2015, 1504.07916.

[26] Sergey E. Koposov,et al. MAGELLAN/M2FS SPECTROSCOPY OF THE RETICULUM 2 DWARF SPHEROIDAL GALAXY , 2015, 1504.03060.

[27] D. Gerdes,et al. STELLAR KINEMATICS AND METALLICITIES IN THE ULTRA-FAINT DWARF GALAXY RETICULUM II , 2015, 1504.02889.

[28] S. Majewski,et al. HYDRA II: A FAINT AND COMPACT MILKY WAY DWARF GALAXY FOUND IN THE SURVEY OF THE MAGELLANIC STELLAR HISTORY , 2015, 1503.06216.

[29] H. Rix,et al. A NEW FAINT MILKY WAY SATELLITE DISCOVERED IN THE PAN-STARRS1 3π SURVEY , 2015, 1503.05554.

[30] B. Yanny,et al. EIGHT NEW MILKY WAY COMPANIONS DISCOVERED IN FIRST-YEAR DARK ENERGY SURVEY DATA , 2015, 1503.02584.

[31] Sergey E. Koposov,et al. BEASTS OF THE SOUTHERN WILD: DISCOVERY OF NINE ULTRA FAINT SATELLITES IN THE VICINITY OF THE MAGELLANIC CLOUDS , 2015, 1503.02079.

[32] L. Casagrande,et al. Iron and s-elements abundance variations in NGC 5286: Comparison with 'anomalous' globular clusters and Milky Way satellites , 2015, 1502.07438.

[33] J. Frieman,et al. The LMC geometry and outer stellar populations from early DES data , 2015, 1502.05050.

[34] A. Milone,et al. DISCOVERY OF A FAINT OUTER HALO MILKY WAY STAR CLUSTER IN THE SOUTHERN SKY , 2015, 1502.03952.

[35] H. Jerjen,et al. A HERO'S LITTLE HORSE: DISCOVERY OF A DISSOLVING STAR CLUSTER IN PEGASUS , 2014, 1411.3063.

[36] A. Dotter,et al. The halo+cluster system of the galactic globular cluster NGC 1851 , 2014, 1406.0944.

[37] H. Rix,et al. A NEW DISTANT MILKY WAY GLOBULAR CLUSTER IN THE PAN-STARRS1 3π SURVEY , 2014, 1403.6593.

[38] L. Costa,et al. A NEW MILKY WAY HALO STAR CLUSTER IN THE SOUTHERN GALACTIC SKY , 2012, 1212.5952.

[39] R. Ibata,et al. Do globular clusters possess dark matter haloes? A case study in NGC 2419 , 2012, 1210.7787.

[40] Daniel Foreman-Mackey,et al. emcee: The MCMC Hammer , 2012, 1202.3665.

[41] L. Girardi,et al. parsec: stellar tracks and isochrones with the PAdova and TRieste Stellar Evolution Code , 2012, 1208.4498.

[42] Emmanuel Bertin,et al. The Dark Energy Survey data processing and calibration system , 2012, Other Conferences.

[43] S. Djorgovski,et al. THE DISCOVERY OF AN ULTRA-FAINT STAR CLUSTER IN THE CONSTELLATION OF URSA MINOR , 2012, 1204.5750.

[44] Alan W. McConnachie,et al. THE OBSERVED PROPERTIES OF DWARF GALAXIES IN AND AROUND THE LOCAL GROUP , 2012, 1204.1562.

[45] J. Mohr,et al. THE BLANCO COSMOLOGY SURVEY: DATA ACQUISITION, PROCESSING, CALIBRATION, QUALITY DIAGNOSTICS, AND DATA RELEASE , 2012, 1204.1210.

[46] B. Willman,et al. “GALAXY,” DEFINED , 2012, 1203.2608.

[47] B. Willman,et al. SEGUE 3: AN OLD, EXTREMELY LOW LUMINOSITY STAR CLUSTER IN THE MILKY WAY's HALO , 2011, 1107.3151.

[48] A. Helmi,et al. The population of Milky Way satellites in the LambdaCDM cosmology , 2011, 1103.0024.

[49] Elena Pierpaoli,et al. AN OPTICAL CATALOG OF GALAXY CLUSTERS OBTAINED FROM AN ADAPTIVE MATCHED FILTER FINDER APPLIED TO SLOAN DIGITAL SKY SURVEY DATA RELEASE 6 , 2010, 1011.0249.

[50] J. G. Jernigan,et al. Astronomical Data Analysis Software and Systems XX , 2011 .

[51] W. Harris. A New Catalog of Globular Clusters in the Milky Way , 2010, 1012.3224.

[52] S. Majewski,et al. ASSESSING THE MILKY WAY SATELLITES ASSOCIATED WITH THE SAGITTARIUS DWARF SPHEROIDAL GALAXY , 2010, 1005.5390.

[53] Tucson,et al. BIG FISH, LITTLE FISH: TWO NEW ULTRA-FAINT SATELLITES OF THE MILKY WAY , 2010, 1002.0504.

[54] Gregory D. Martinez,et al. Accurate masses for dispersion-supported galaxies , 2009, 0908.2995.

[55] Eric Neilsen,et al. The Dark Energy Survey data management system , 2008, Astronomical Telescopes + Instrumentation.

[56] Heidelberg,et al. A Comprehensive Maximum Likelihood Analysis of the Structural Properties of Faint Milky Way Satellites , 2008, 0805.2945.

[57] W. B. Burton,et al. The Origin of the Magellanic Stream and Its Leading Arm , 2007, 0706.1578.

[58] Sergey E. Koposov,et al. Accepted for publication in ApJ Preprint typeset using L ATEX style emulateapj v. 02/07/07 THE DISCOVERY OF TWO EXTREMELY LOW LUMINOSITY MILKY WAY GLOBULAR CLUSTERS , 2022 .

[59] B. Flaugher. The Dark Energy Survey , 2005 .

[60] Princeton,et al. The Sloan Digital Sky Survey View of the Palomar-Green Bright Quasar Survey , 2005, astro-ph/0506022.

[61] A. Mackey,et al. Comparing the properties of local globular cluster systems: implications for the formation of the Galactic halo , 2004, astro-ph/0408404.

[62] Walter Dehnen,et al. A Matched-Filter Analysis of the Tidal Tails of the Globular Cluster Palomar 5 , 2002 .

[63] P. Kroupa. On the variation of the initial mass function , 2000, astro-ph/0009005.

[64] Walter A. Siegmund,et al. The Sloan Digital Sky Survey: Technical Summary , 2000, astro-ph/0006396.

[65] D. Schlegel,et al. Maps of Dust Infrared Emission for Use in Estimation of Reddening and Cosmic Microwave Background Radiation Foregrounds , 1998 .

[66] E. Bertin,et al. SExtractor: Software for source extraction , 1996 .

[67] M. Irwin,et al. A dwarf satellite galaxy in Sagittarius , 1994, Nature.

[68] Philippe Fischer,et al. The Carina dwarf spheroidal galaxy: how dark is it? , 1993 .

[69] John E. Hibbard,et al. The globular cluster-galaxy connection , 1993 .

[70] R. Zinn. The globular cluster system of the galaxy. IV - The halo and disk subsystems , 1985 .

[71] G. Efstathiou,et al. The evolution of large-scale structure in a universe dominated by cold dark matter , 1985 .

[72] M. Rees,et al. Core condensation in heavy halos: a two-stage theory for galaxy formation and clustering , 1978 .

[73] H. Plummer. On the Problem of Distribution in Globular Star Clusters: (Plate 8.) , 1911 .