@article{dd011268d37d4791b71f690d4b5f7799,
title = "The Hubble Space Telescope Survey of M31 Satellite Galaxies. I. RR Lyrae–based Distances and Refined 3D Geometric Structure",
abstract = "We measure homogeneous distances to M31 and 38 associated stellar systems (−16.8 ≤ MV ≤ −6.0), using time-series observations of RR Lyrae stars taken as part of the Hubble Space Telescope Treasury Survey of M31 Satellites. From >700 orbits of new/archival Advanced Camera for Surveys imaging, we identify >4700 RR Lyrae stars and determine their periods and mean magnitudes to a typical precision of 0.01 day and 0.04 mag. Based on period–Wesenheit–metallicity relationships consistent with the Gaia eDR3 distance scale, we uniformly measure heliocentric and M31-centric distances to a typical precision of ∼20 kpc (3%) and ∼10 kpc (8%), respectively. We revise the 3D structure of the M31 galactic ecosystem and: (i) confirm a highly anisotropic spatial distribution such that ∼80% of M31's satellites reside on the near side of M31; this feature is not easily explained by observational effects; (ii) affirm the thin (rms 7–23 kpc) planar “arc” of satellites that comprises roughly half (15) of the galaxies within 300 kpc from M31; (iii) reassess the physical proximity of notable associations such as the NGC 147/185 pair and M33/AND XXII; and (iv) illustrate challenges in tip-of-the-red-giant branch distances for galaxies with MV > − 9.5, which can be biased by up to 35%. We emphasize the importance of RR Lyrae for accurate distances to faint galaxies that should be discovered by upcoming facilities (e.g., Rubin Observatory). We Original content from this work may be used under the terms of the Creative Commons Attribution 4.0 licence. Any further provide updated luminosities and sizes for our sample. Our distances will serve as the basis for future investigation of the star formation and orbital histories of the entire known M31 satellite system.",
author = "Alessandro Savino and Weisz, {Daniel R.} and Skillman, {Evan D.} and Andrew Dolphin and Nitya Kallivayalil and Andrew Wetzel and Jay Anderson and Gurtina Besla and Michael Boylan-Kolchin and Bullock, {James S.} and Cole, {Andrew A.} and Collins, {Michelle L.M.} and Cooper, {M. C.} and Deason, {Alis J.} and Dotter, {Aaron L.} and Mark Fardal and Ferguson, {Annette M.N.} and Fritz, {Tobias K.} and Geha, {Marla C.} and Gilbert, {Karoline M.} and Puragra Guhathakurta and Rodrigo Ibata and Irwin, {Michael J.} and Myoungwon Jeon and Evan Kirby and Lewis, {Geraint F.} and Dougal Mackey and Majewski, {Steven R.} and Nicolas Martin and Alan McConnachie and Ekta Patel and {Michael Rich}, R. and Simon, {Joshua D.} and Sohn, {Sangmo Tony} and Tollerud, {Erik J.} and {van der Marel}, {Roeland P.}",
note = "Funding Information: A.S. thanks Y. Zheng for useful discussions at various stages of this work. Support for this work was provided by NASA through grants GO-13768, GO-15746, GO-15902, AR-16159, and GO-16273 from the Space Telescope Science Institute, which is operated by AURA, Inc., under NASA contract NAS5-26555. M.C.C. acknowledges support though NSF grant AST-1815475. M.B.K. acknowledges support from NSF CAREER award AST-1752913, NSF grants AST-1910346 and AST-2108962, NASA grant NNX17AG29G, and HST-AR-15006, HST-AR-15809, HST-GO-15658, HST-GO-15901, HST-GO-15902, HST-AR-16159, and HST-GO-16226 from STScI. A.S. wishes to thank M. Marconi and R. Molinaro for providing the PWZ scaling relations used in this paper. This research has made use of NASA's Astrophysics Data System Bibliographic Services. All of the HST data used in this paper can be found in MAST: 10.17909/jb41-ex86 . Publisher Copyright: {\textcopyright} 2022. The Author(s). Published by the American Astronomical Society.",
year = "2022",
month = oct,
day = "1",
doi = "10.3847/1538-4357/ac91cb",
language = "English (US)",
volume = "938",
journal = "Astrophysical Journal",
issn = "0004-637X",
publisher = "IOP Publishing Ltd.",
number = "2",
}