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NAME Tri II , the SIMBAD biblio (131 results) | C.D.S. - SIMBAD4 rel 1.8 - 2024.06.16CEST14:59:20 |
Bibcode/DOI | Score |
in Title|Abstract| Keywords |
in a table | in teXt, Caption, ... | Nb occurence | Nb objects in ref |
Citations (from ADS) |
Title | First 3 Authors |
---|---|---|---|---|---|---|---|---|---|
2015ApJ...802L..18L | 1140 | A | X C | 28 | 16 | 136 | A new faint Milky Way satellite discovered in the Pan-STARRS1 3π survey. | LAEVENS B.P.M., MARTIN N.F., IBATA R.A., et al. | |
2015ApJ...804L...5M | 85 | C | 1 | 10 | 138 | Hydra II: a faint and compact Milky Way dwarf galaxy found in the survey of the Magellanic stellar history. | MARTIN N.F., NIDEVER D.L., BESLA G., et al. | ||
2015AJ....150..160B | 79 | C | 1 | 38 | 21 | Charting unexplored dwarf galaxy territory with RR Lyrae. | BAKER M. and WILLMAN B. | ||
2015ApJ...813...44L | 202 | X C | 4 | 28 | 199 | Sagittarius II, Draco II and Laevens 3: three new Milky Way satellites discovered in the Pan-STARRS 1 3π survey. | LAEVENS B.P.M., MARTIN N.F., BERNARD E.J., et al. | ||
2015ApJ...814L...7K | 2089 | A | X C | 52 | 27 | 36 |
Triangulum II: possibly a very dense ultra-faint dwarf galaxy. |
KIRBY E.N., COHEN J.G., SIMON J.D., et al. | |
2015MNRAS.453.1047P | 453 | D | X C F | 10 | 59 | 57 | The new Milky Way satellites: alignment with the VPOS and predictions for proper motions and velocity dispersions. | PAWLOWSKI M.S., McGAUGH S.S. and JERJEN H. | |
2016ApJ...818...40M | 2272 | T K A | X C | 55 | 62 | 24 | Triangulum II: a very metal-poor and dynamically hot stellar system. | MARTIN N.F., IBATA R.A., COLLINS M.L.M., et al. | |
2016MNRAS.460.4397C | 901 | A | X C | 21 | 2 | 69 | Ultra-light dark matter in ultra-faint dwarf galaxies. | CALABRESE E. and SPERGEL D.N. | |
2016MNRAS.461.2914H | 563 | A | D | X F | 14 | 28 | 51 | Dark matter annihilation and decay from non-spherical dark halos in galactic dwarf satellites. | HAYASHI K., ICHIKAWA K., MATSUMOTO S., et al. |
2016MNRAS.462.2734H | 16 | D | 1 | 8 | 2 | Theoretical lower limits on sizes of ultrafaint dwarf galaxies from dynamical friction. | HERNANDEZ X. | ||
2017ApJ...834..110A | 9 | 50 | 477 | Searching for dark matter annihilation in recently discovered Milky Way satellites with Fermi-Lat. | ALBERT A., ANDERSON B., BECHTOL K., et al. | ||||
2017AJ....153....6K | 16 | D | 1 | 405 | 10 | The Local Tully-Fisher relation for dwarf galaxies. | KARACHENTSEV I.D., KAISINA E.I. and KASHIBADZE O.G. | ||
2016MNRAS.463.3630G | 1246 | T A | D | S X C F | 28 | 5 | 11 |
The potential of the dwarf galaxy Triangulum II for dark matter indirect detection. |
GENINA A. and FAIRBAIRN M. |
2017ApJ...838...11S | 41 | X | 1 | 127 | 88 | Nearest neighbor: the low-mass Milky Way satellite Tucana III. | SIMON J.D., LI T.S., DRLICA-WAGNER A., et al. | ||
2017ApJ...838...83K | 2560 | T A | D | X C | 62 | 44 | 87 |
Triangulum II. Not especially dense after all. |
KIRBY E.N., COHEN J.G., SIMON J.D., et al. |
2017MNRAS.466.1741C | 81 | C | 1 | 38 | 7 | The contribution of dissolving star clusters to the population of ultra faint objects in the outer halo of the Milky Way. | CONTENTA F., GIELES M., BALBINOT E., et al. | ||
2017MNRAS.466.3741V | 1828 | T K A | D | S X C | 43 | 24 | 15 |
Gemini/GRACES spectroscopy of stars in Tri II. |
VENN K.A., STARKENBURG E., MALO L., et al. |
2017MNRAS.467..573C | 81 | X | 2 | 42 | 27 | Dynamical evidence for a strong tidal interaction between the Milky Way and its satellite, Leo V. | COLLINS M.L.M., TOLLERUD E.J., SAND D.J., et al. | ||
2017MNRAS.468.2359W | 612 | X C F | 13 | 11 | 40 | On the run: mapping the escape speed across the Galaxy with SDSS. | WILLIAMS A.A., BELOKUROV V., CASEY A.R., et al. | ||
2017MNRAS.470.1086C | 97 | D | F | 3 | 17 | ~ | MONDian predictions for Newtonian mass-to-light ratios for ultrafaint dSphs. | CORTES R.A.M. and HERNANDEZ X. | |
2017ApJ...850..179C | 41 | X | 1 | 28 | 7 | The universality of the rapid neutron-capture process revealed by a possible disrupted dwarf galaxy star. | CASEY A.R. and SCHLAUFMAN K.C. | ||
2017AJ....154..267C | 4689 | T | D | S X C | 113 | 7 | 19 |
Deep Subaru Hyper Suprime-Cam observations of Milky Way satellites Columba I and Triangulum II. |
CARLIN J.L., SAND D.J., MUNOZ R.R., et al. |
2018ApJ...852...68C | 247 | X C | 5 | 41 | 23 | On the nature of ultra-faint dwarf galaxy candidates. I. DES1, Eridanus III, and Tucana V. | CONN B.C., JERJEN H., KIM D., et al. | ||
2018ApJ...852...99N | 82 | C | 1 | 28 | 13 | Chemical abundance analysis of three α-poor, metal-poor stars in the ultrafaint dwarf galaxy Horologium I. | NAGASAWA D.Q., MARSHALL J.L., LI T.S., et al. | ||
2017MNRAS.472.2670S | 16 | D | 1 | 69 | 5 | The shapes and alignments of the satellites of the Milky Way and Andromeda. | SANDERS J.L. and EVANS N.W. | ||
2018ApJ...853..154A | 595 | D | X C | 14 | 16 | 41 | Dark matter limits from dwarf spheroidal galaxies with the HAWC gamma-ray observatory. | ALBERT A., ALFARO R., ALVAREZ C., et al. | |
2018A&A...609A..11K | 99 | D | C | 2 | 229 | 7 | Cosmic flow around local massive galaxies. | KASHIBADZE O.G. and KARACHENTSEV I.D. | |
2018A&A...611A..81M | 41 | X | 1 | 24 | ~ | Bose-Einstein condensate haloes embedded in dark energy. | MEMBRADO M. and PACHECO A.F. | ||
2018MNRAS.475.5385D | 58 | D | X | 2 | 26 | 4 | Phase-space mass bound for fermionic dark matter from dwarf spheroidal galaxies. | DI PAOLO C., NESTI F. and VILLANTE F.L. | |
2018ApJ...860...65M | 181 | D | X | 5 | 66 | 6 | A MegaCAM Survey of outer halo satellites. I. Description of the Survey. | MUNOZ R.R., COTE P., SANTANA F.A., et al. | |
2018ApJ...860...66M | 264 | D | X | 7 | 95 | 119 | A MegaCAM survey of outer halo satellites. III. Photometric and structural parameters. | MUNOZ R.R., COTE P., SANTANA F.A., et al. | |
2018ApJ...863...89S | 576 | A | D | X C | 14 | 1159 | 133 | Gaia proper motions and orbits of the ultra-faint Milky Way satellites. | SIMON J.D. |
2018ApJ...865....7C | 82 | X | 2 | 37 | 10 | Bootes III is a disrupting dwarf galaxy associated with the Styx stellar stream. | CARLIN J.L. and SAND D.J. | ||
2018MNRAS.479.2853N | 17 | D | 1 | 57 | 106 | The total satellite population of the Milky Way. | NEWTON O., CAUTUN M., JENKINS A., et al. | ||
2018MNRAS.479.4136K | 16 | D | 1 | 1019 | 3 | Morphological properties of galaxies in different Local Volume environments. | KARACHENTSEV I.D., KAISINA E.I. and MAKAROV D.I. | ||
2018ApJ...867...19K | 167 | A | D | X | 5 | 39 | 115 | The missing satellites of the Magellanic Clouds? Gaia proper motions of the recently discovered ultra-faint galaxies. | KALLIVAYALIL N., SALES L.V., ZIVICK P., et al. |
2018A&A...619A.103F | 266 | D | X | 7 | 56 | 221 | Gaia DR2 proper motions of dwarf galaxies within 420 kpc. Orbits, Milky Way mass, tidal influences, planar alignments, and group infall. | FRITZ T.K., BATTAGLIA G., PAWLOWSKI M.S., et al. | |
2019ApJ...870...83J | 1907 | T K A | S X C | 43 | 32 | 61 |
Chemical abundances in the ultra-faint dwarf galaxies Grus I and Triangulum II: neutron-capture elements as a defining feature of the faintest dwarfs. |
JI A.P., SIMON J.D., FREBEL A., et al. | |
2019MNRAS.483.1314B | 18 | D | 1 | 82 | 97 | NIHAO XV: the environmental impact of the host galaxy on galactic satellite and field dwarf galaxies. | BUCK T., MACCIO A.V., DUTTON A.A., et al. | ||
2017PASJ...69...76S | 244 | X C | 5 | 50 | 23 | Stellar Abundances for Galactic Archaeology Database. IV. Compilation of stars in dwarf galaxies. | SUDA T., HIDAKA J., AOKI W., et al. | ||
2019MNRAS.482.3480P | 226 | D | X C | 5 | 60 | 20 | Scaling relations for dark matter annihilation and decay profiles in dwarf spheroidal galaxies. | PACE A.B. and STRIGARI L.E. | |
2019MNRAS.483.2000L | 17 | D | 1 | 14 | 5 | The abundance of satellite galaxies in the inner region of ΛCDM Milky Way sized haloes. | LI M., GAO L. and WANG J. | ||
2019MNRAS.483.4031W | 84 | F | 1 | 43 | ~ | The suppression of star formation on the smallest scales: what role does environment play? | WIMBERLY M.K.R., COOPER M.C., FILLINGHAM S.P., et al. | ||
2019ApJ...871..247B | 42 | X | 1 | 21 | 7 | The origin of r-process enhanced metal-poor halo stars in now-destroyed ultra-faint dwarf galaxies. | BRAUER K., JI A.P., FREBEL A., et al. | ||
2019ApJ...874...29M | 17 | D | 1 | 78 | 2 | A MegaCAM survey of outer halo satellites. VII. A single Sersic index versus effective radius relation for Milky Way outer halo satellites. | MARCHI-LASCH S., MUNOZ R.R., SANTANA F.A., et al. | ||
2019MNRAS.486.2679R | 17 | D | 2 | 46 | 8 | The velocity anisotropy of the Milky Way satellite system. | RILEY A.H., FATTAHI A., PACE A.B., et al. | ||
2019ApJ...878...97Y | 42 | X | 1 | 15 | 6 | Origin of the CEMP-no group morphology in the Milky Way. | YOON J., BEERS T.C., TIAN D., et al. | ||
2019MNRAS.487.2961M | 47 | X | 1 | 5 | 28 | Robust velocity dispersion and binary population modelling of the ultrafaint dwarf galaxy Reticulum II. | MINOR Q.E., PACE A.B., MARSHALL J.L., et al. | ||
2019MNRAS.488.4585G | 19 | D | 1 | 21 | 43 | How low does it go? Too few Galactic satellites with standard reionization quenching. | GRAUS A.S., BULLOCK J.S., KELLEY T., et al. | ||
2019ApJ...882..177M | 42 | X | 1 | 25 | 10 | Chemical abundance analysis of Tucana III, the second r-process enhanced ultra-faint dwarf galaxy. | MARSHALL J.L., HANSEN T., SIMON J.D., et al. | ||
2019ApJ...883...84R | 42 | X | 1 | 49 | ~ | High-resolution optical spectroscopy of stars in the Sylgr stellar stream. | ROEDERER I.U. and GNEDIN O.Y. | ||
2019ApJ...883..171H | 42 | X | 1 | 54 | 5 | On the absence of dark matter in dwarf galaxies surrounding the Milky Way. | HAMMER F., YANG Y., WANG J., et al. | ||
2019ApJ...885...33H | 125 | X C | 2 | 23 | ~ | Enrichment of strontium in dwarf galaxies. | HIRAI Y., WANAJO S. and SAITOH T.R. | ||
2019ApJ...885...53M | 84 | X | 2 | 142 | ~ | Signatures of tidal disruption in ultra-faint dwarf galaxies: a combined HST, Gaia, and MMT/Hectochelle study of Leo V. | MUTLU-PAKDIL B., SAND D.J., WALKER M.G., et al. | ||
2019MNRAS.490.5647M | 17 | D | 1 | 1738 | ~ | Searching for correlations in Gaia DR2 unbound star trajectories. | MONTANARI F., BARRADO D. and GARCIA-BELLIDO J. | ||
2019PASJ...71...94H | 1 | 30 | 40 | Boötes. IV. A new Milky Way satellite discovered in the Subaru Hyper Suprime-Cam Survey and implications for the missing satellite problem. | HOMMA D., CHIBA M., KOMIYAMA Y., et al. | ||||
2020MNRAS.491.3496C | 170 | X | 4 | 86 | 26 | A detailed study of Andromeda XIX, an extreme local analogue of ultradiffuse galaxies. | COLLINS M.L.M., TOLLERUD E.J., RICH R.M., et al. | ||
2020ApJ...889...27J | 43 | X | 1 | 36 | 31 | Detailed abundances in the ultra-faint Magellanic satellites Carina II and III. | JI A.P., LI T.S., SIMON J.D., et al. | ||
2020MNRAS.492.3241V | 43 | X | 1 | 134 | 41 | The Pristine survey - IX. CFHT ESPaDOnS spectroscopic analysis of 115 bright metal-poor candidate stars. | VENN K.A., KIELTY C.L., SESTITO F., et al. | ||
2020MNRAS.492.5247S | 315 | D | X F | 7 | 27 | ~ | Improved constraints from ultra-faint dwarf galaxies on primordial black holes as dark matter. | STEGMANN J., CAPELO P.R., BORTOLAS E., et al. | |
2020A&A...634A..10H | 43 | X | 1 | 62 | ~ | Kinematic and metallicity properties of the Aquarius dwarf galaxy from FORS2 MXU spectroscopy. | HERMOSA MUNOZ L., TAIBI S., BATTAGLIA G., et al. | ||
2020ApJS..247...35V | 187 | D | X | 5 | 101 | ~ | Gaia RR Lyrae stars in nearby ultra-faint dwarf satellite galaxies. | VIVAS A.K., MARTINEZ-VAZQUEZ C. and WALKER A.R. | |
2020ApJ...892....3H | 170 | X C | 3 | 32 | 29 | Orbital evidences for dark-matter-free Milky Way dwarf spheroidal galaxies. | HAMMER F., YANG Y., ARENOU F., et al. | ||
2020ApJ...892...27M | 17 | D | 1 | 45 | ~ | Stellar density profiles of dwarf spheroidal galaxies. | MOSKOWITZ A.G. and WALKER M.G. | ||
2020ApJ...893...21S | 138 | X | 3 | 8 | 87 | Ultra-light dark matter is incompatible with the Milky Way's dwarf satellites. | SAFARZADEH M. and SPERGEL D.N. | ||
2020ApJ...893...47D | 18 | D | 2 | 67 | 116 | Milky Way satellite census. I. The observational selection function for Milky Way satellites in DES y3 and Pan-STARRS DR1. | DRLICA-WAGNER A., BECHTOL K., MAU S., et al. | ||
2020ApJ...893...48N | 19 | D | 1 | 43 | 102 | Milky Way satellite census. II. Galaxy-halo connection constraints including the impact of the Large Magellanic Cloud. | NADLER E.O., WECHSLER R.H., BECHTOL K., et al. | ||
2020A&A...636A.111A | 85 | C | 1 | 44 | ~ | Chemical abundance analysis of extremely metal-poor stars in the Sextans dwarf spheroidal galaxy. | AOKI M., AOKI W. and FRANCOIS P. | ||
2020MNRAS.494.5178F | 17 | D | 1 | 56 | 40 | The mass of our Galaxy from satellite proper motions in the Gaia era. | FRITZ T.K., DI CINTIO A., BATTAGLIA G., et al. | ||
2020MNRAS.495.2554E | 18 | D | 2 | 49 | 79 | Limit on the LMC mass from a census of its satellites. | ERKAL D. and BELOKUROV V.A. | ||
2020MNRAS.495.3276L | 255 | X C | 5 | 19 | ~ | Chemical evolution of ultrafaint dwarf galaxies: testing the IGIMF. | LACCHIN E., MATTEUCCI F., VINCENZO F., et al. | ||
2020ApJ...897..183H | 43 | X | 1 | 32 | ~ | Chemical analysis of the ultrafaint dwarf galaxy Grus II. Signature of high-mass stellar Nucleosynthesis. | HANSEN T.T., MARSHALL J.L., SIMON J.D., et al. | ||
2020MNRAS.497.1236M | 43 | X | 1 | 67 | 48 | Chemo-dynamics of outer halo dwarf stars, including Gaia-Sausage and Gaia-Sequoia candidates. | MONTY S., VENN K.A., LANE J.M.M., et al. | ||
2020AJ....160..124M | 17 | D | 7 | 174 | 54 | Revised and new proper motions for confirmed and candidate Milky Way dwarf galaxies. | McCONNACHIE A.W. and VENN K.A. | ||
2020A&A...641A.127R | 170 | A | D | X | 5 | 401 | 41 | Neutron-capture elements in dwarf galaxies. III. A homogenized analysis of 13 dwarf spheroidal and ultra-faint galaxies. | REICHERT M., HANSEN C.J., HANKE M., et al. |
2020MNRAS.499.3755S | 85 | C | 1 | 103 | ~ | An updated detailed characterization of planes of satellites in the MW and M31. | SANTOS-SANTOS I.M., DOMINGUEZ-TENREIRO R. and PAWLOWSKI M.S. | ||
2020ApJ...904..161B | 64 | X | 1 | 3 | 64 | Fuzzy dark matter and dark matter halo cores. | BURKERT A. | ||
2021MNRAS.500..986H | 17 | D | 1 | 69 | ~ | Search for globular clusters associated with the Milky Way dwarf galaxies using Gaia DR2. | HUANG K.-W. and KOPOSOV S.E. | ||
2021MNRAS.500.2937A | 261 | A | D | X | 7 | 178 | ~ | The orbital evolution of UFDs and GCs in an evolving Galactic potential. | ARMSTRONG B.M., BEKKI K. and LUDLOW A.D. |
2021MNRAS.500.5589H | 17 | D | 1 | 46 | ~ | Addressing γ-ray emissions from dark matter annihilations in 45 Milky Way satellite galaxies and in extragalactic sources with particle dark matter models. | HALDER A., BANERJEE S., PANDEY M., et al. | ||
2021ApJ...908...18S | 45 | X | 1 | 25 | 34 | Eridanus II: a fossil from reionization with an off-center star cluster. | SIMON J.D., BROWN T.M., DRLICA-WAGNER A., et al. | ||
2021MNRAS.504.1183S | 1959 | T A | D | S X C F | 42 | 38 | 4 |
The formation of the milky way halo and its dwarf satellites: a NLTE-1D abundance analysis. IV. Segue 1, Triangulum II, and Coma Berenices UFDs. |
SITNOVA T.M., MASHONKINA L.I., TATARNIKOV A.M., et al. |
2021ApJ...912L...3H | 88 | X | 2 | 20 | 36 | Narrowing the mass range of fuzzy dark matter with ultrafaint dwarfs. | HAYASHI K., FERREIRA E.G.M. and CHAN H.Y.J. | ||
2021NatAs...5..478M | 17 | D | 1 | 45 | ~ | Destruction of the central black hole gas reservoir through head-on galaxy collisions. | MIKI Y., MORI M. and KAWAGUCHI T. | ||
2021ApJ...913...25C | 44 | X | 1 | 11 | ~ | Model-independent constraints on ultralight dark matter from the SPARC data. | CHAN M.H. and YEUNG C.F. | ||
2021ApJ...913...53P | 148 | D | X | 4 | 123 | 72 | The gas content and stripping of Local Group dwarf galaxies. | PUTMAN M.E., ZHENG Y., PRICE-WHELAN A.M., et al. | |
2021MNRAS.504.4551S | 104 | D | F | 5 | 55 | 23 | Magellanic satellites in ΛCDM cosmological hydrodynamical simulations of the Local Group. | SANTOS-SANTOS I.M.E., FATTAHI A., SALES L.V., et al. | |
2021ApJ...914L..37S | 87 | X | 2 | 32 | 6 | The challenge to MOND from ultra-faint dwarf galaxies. | SAFARZADEH M. and LOEB A. | ||
2021MNRAS.505.3755T | 218 | X C F | 3 | 23 | 6 | s-process enrichment of ultrafaint dwarf galaxies. | TARUMI Y., SUDA T., VAN DE VOORT F., et al. | ||
2021ApJ...916....8L | 322 | D | X | 8 | 56 | 53 | Gaia EDR3 proper motions of Milky Way dwarfs. I. 3D motions and orbits. | LI H., HAMMER F., BABUSIAUX C., et al. | |
2021ApJ...916...27D | 52 | X | 1 | 3 | 24 | On the random motion of nuclear objects in a fuzzy dark matter halo. | DUTTA CHOWDHURY D., VAN DEN BOSCH F.C., ROBLES V.H., et al. | ||
2021MNRAS.507.3246H | 17 | D | 1 | 4479 | 15 | The nucleation fraction of local volume galaxies. | HOYER N., NEUMAYER N., GEORGIEV I.Y., et al. | ||
2021ApJ...920L..19S | 45 | A | D | 4 | 15 | 21 | Star formation histories of ultra-faint dwarf galaxies: environmental differences between magellanic and non-magellanic satellites? | SACCHI E., RICHSTEIN H., KALLIVAYALIL N., et al. | |
2021ApJ...922...93H | 174 | X C | 3 | 49 | 13 | Gaia EDR3 proper motions of Milky Way dwarfs. II. Velocities, total energy, and angular momentum. | HAMMER F., WANG J., PAWLOWSKI M.S., et al. | ||
2022MNRAS.509...16M | 117 | A | C | 5 | 9 | 13 | Pisces VII: discovery of a possible satellite of Messier 33 in the DESI legacy imaging surveys. | MARTINEZ-DELGADO D., KARIM N., CHARLES E.J.E., et al. | |
2021ApJ...923...77P | 44 | X | 1 | 3270 | 13 | Spectroscopic confirmation of the sixth globular cluster in the Fornax dwarf spheroidal galaxy. | PACE A.B., WALKER M.G., KOPOSOV S.E., et al. | ||
2022ApJ...924..131S | 18 | D | 1 | 39 | 6 | Galactic Mass estimates using dwarf galaxies as kinematic tracers. | SLIZEWSKI A., DUFRESNE X., MURDOCK K., et al. | ||
2022A&A...657A..54B | 376 | D | X | 9 | 87 | 68 | Gaia early DR3 systemic motions of Local Group dwarf galaxies and orbital properties with a massive Large Magellanic Cloud. | BATTAGLIA G., TAIBI S., THOMAS G.F., et al. | |
2022MNRAS.510.2186G | 46 | X | 1 | 11 | 21 | Can tides explain the low dark matter density in Fornax? | GENINA A., READ J.I., FATTAHI A., et al. | ||
2022MNRAS.510.3531B | 421 | D | S X F | 8 | 66 | 9 | Stellar mass segregation as separating classifier between globular clusters and ultrafaint dwarf galaxies. | BAUMGARDT H., FALLER J., MEINHOLD N., et al. | |
2022MNRAS.510.3575H | 45 | X | 1 | 26 | 1 | Identifying RR Lyrae in the ZTF DR3 data set. | HUANG K.-W. and KOPOSOV S.E. | ||
2022MNRAS.511.2610C | 45 | X | 1 | 79 | 27 | Measuring the Milky Way mass distribution in the presence of the LMC. | CORREA MAGNUS L. and VASILIEV E. | ||
2022ApJ...926..106M | 45 | X | 1 | 24 | ~ | Estimate of the Mass and Radial Profile of the Orphan-Chenab Stream's Dwarf-galaxy Progenitor Using | MENDELSOHN E.J., NEWBERG H.J., SHELTON S., et al. | ||
2022MNRAS.512.5671P | 45 | X | 1 | 18 | 3 | Predictions for complex distributions of stellar elemental abundances in low-mass galaxies. | PATEL P.B., LOEBMAN S.R., WETZEL A., et al. | ||
2022ApJ...928...30L | 90 | C | 1 | 53 | 46 | S5: The Orbital and Chemical Properties of One Dozen Stellar Streams. | LI T.S., JI A.P., PACE A.B., et al. | ||
2022MNRAS.513.4968R | 18 | D | 2 | 52 | 8 | Sizing from the smallest scales: the mass of the Milky Way. | RODRIGUEZ WIMBERLY M.K., COOPER M.C., BAXTER D.C., et al. | ||
2022MNRAS.514.1706B | 3297 | T A | S X C | 71 | 8 | 6 |
Stellar kinematics of dwarf galaxies from multi-epoch spectroscopy: application to Triangulum II. |
BUTTRY R., PACE A.B., KOPOSOV S.E., et al. | |
2022AJ....164...48L | 18 | D | 1 | 23 | ~ | Satellite Galaxies' Drag on Field Stars in the Milky Way. | LIANG X., LIU J., ZHAO J., et al. | ||
2022MNRAS.517.6140C | 18 | D | 1 | 30 | ~ | Comparing simulated Milky Way satellite galaxies with observations using unsupervised clustering. | CHEN L.-H., HARTWIG T., KLESSEN R.S., et al. | ||
2022ApJ...940..136P | 421 | D | X C | 9 | 68 | 33 | Proper Motions, Orbits, and Tidal Influences of Milky Way Dwarf Spheroidal Galaxies. | PACE A.B., ERKAL D. and LI T.S. | |
2023A&A...669A..94S | 93 | C | 1 | 16 | 6 | How much metal did the first stars provide to the ultra-faint dwarfs? | SANATI M., JEANQUARTIER F., REVAZ Y., et al. | ||
2023MNRAS.519.5059H | 93 | X | 2 | 185 | 8 | The accretion history of the Milky Way - I. How it shapes globular clusters and dwarf galaxies. | HAMMER F., LI H., MAMON G.A., et al. | ||
2023MNRAS.520.1704B | 19 | D | 1 | 49 | 1 | Determining satellite infall times using machine learning. | BARMENTLOO S. and CAUTUN M. | ||
2023ApJ...945...25A | 112 | D | X | 3 | 41 | 2 | Searching for TeV Dark Matter in Irregular Dwarf Galaxies with HAWC Observatory. | ALFARO R., ALVAREZ C., ARTEAGA-VELAZQUEZ J.C., et al. | |
2023MNRAS.521.3540M | 112 | D | X | 3 | 76 | 4 | The LMC impact on the kinematics of the Milky Way satellites: clues from the running solar apex. | MAKAROV D., KHOPERSKOV S., MAKAROV D., et al. | |
2023MNRAS.522..130R | 19 | D | 2 | 73 | 1 | The SAMI-Fornax Dwarfs Survey - III. Evolution of [α/Fe] in dwarfs, from Galaxy Clusters to the Local Group. | ROMERO-GOMEZ J., PELETIER R.F., AGUERRI J.A.L., et al. | ||
2023ApJ...950..167B | 47 | X | 1 | 58 | 1 | Spectroscopic Analysis of Milky Way Outer Halo Satellites: Aquarius II and Boötes II. | BRUCE J., LI T.S., PACE A.B., et al. | ||
2023MNRAS.519..384E | 215 | A | X F | 4 | 25 | 5 | Dark matter halo cores and the tidal survival of Milky Way satellites. | ERRANI R., NAVARRO J.F., PENARRUBIA J., et al. | |
2023MNRAS.519..871Z | 93 | X | 2 | 41 | 4 | Photometric mass estimation and the stellar mass-halo mass relation for low mass galaxies. | ZARITSKY D. and BEHROOZI P. | ||
2023ApJ...953..185H | 112 | D | X | 3 | 30 | ~ | Dark Matter Halo Properties of the Galactic Dwarf Satellites: Implication for Chemo-dynamical Evolution of the Satellites and a Challenge to Lambda Cold Dark Matter. | HAYASHI K., HIRAI Y., CHIBA M., et al. | |
2023A&A...676A..63B | 47 | X | 1 | 27 | ~ | Confronting fuzzy dark matter with the rotation curves of nearby dwarf irregular galaxies. | BANARES-HERNANDEZ A., CASTILLO A., MARTIN CAMALICH J., et al. | ||
2023ApJ...953....1C | 327 | X | 7 | 53 | ~ | Six More Ultra-faint Milky Way Companions Discovered in the DECam Local Volume Exploration Survey. | CERNY W., MARTINEZ-VAZQUEZ C.E., DRLICA-WAGNER A., et al. | ||
2023MNRAS.525..325K | 19 | D | 1 | 55 | ~ | Densities and mass assembly histories of the Milky Way satellites are not a challenge to ΛCDM. | KRAVTSOV A. and WU Z. | ||
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