The Importance of Preventive Feedback: Inference from Observations of the Stellar Masses and Metallicities of Milky Way Dwarf Galaxies
Abstract
Dwarf galaxies are known to have remarkably low star formation efficiency due to strong feedback. Adopting the dwarf galaxies of the Milky Way (MW) as a laboratory, we explore a flexible semi-analytic galaxy formation model to understand how the feedback processes shape the satellite galaxies of the MW. Using Markov Chain Monte Carlo, we exhaustively search a large parameter space of the model and rigorously show that the general wisdom of strong outflows as the primary feedback mechanism cannot simultaneously explain the stellar mass function and the mass–metallicity relation of the MW satellites. An extended model that assumes that a fraction of baryons is prevented from collapsing into low-mass halos in the first place can be accurately constrained to simultaneously reproduce those observations. The inference suggests that two different physical mechanisms are needed to explain the two different data sets. In particular, moderate outflows with weak halo mass dependence are needed to explain the mass–metallicity relation, and prevention of baryons falling into shallow gravitational potentials of low-mass halos (e.g., "pre-heating") is needed to explain the low stellar mass fraction for a given subhalo mass.
Additional Information
© 2017 American Astronomical Society. Received 2017 March 21. Accepted 2017 August 4. Published 2017 August 31. We acknowledge the Ahmanson Foundation for providing computational resources used in this work. The zoom-in simulations were performed using computational resources of SLAC National Accelerator Laboratory and of the National Energy Research Scientific Computing Center. We thank the SLAC computational team for their consistent support. Support for programs HST-AR-13896, HST-AR-13888, HST-AR-13270, HST-AR-12836, and HST-GO-14734 was provided by NASA through a grant from the Space Telescope Science Institute (STScI), which is operated by the Association of Universities for Research in Astronomy, Inc., under NASA contract NAS 5-26555. We are grateful to Takashi Okamoto for providing tabulated data for the critical mass as a function of redshift presented in Okamoto et al. (2008). Y.L. thanks Romeel Davé Phil Hopkins, Evan Kirby, Houjun Mo, Josh Simon, and Qingjuan Yu for helpful discussion. A.W. was supported by a Caltech-Carnegie Fellowship, in part through the Moore Center for Theoretical Cosmology and Physics at Caltech. Y.Y.M. is supported by the Samuel P. Langley PITT PACC Postdoctoral Fellowship, and was supported by the Weiland Family Stanford Graduate Fellowship. S.T. was supported by the Alvin E. Nashman Fellowship. M.B.K. acknowledges support from NSF grant AST-1517226 in addition to the HST grants listed above.Attached Files
Published - Lu_2017_ApJ_846_66.pdf
Submitted - 1703.07467.pdf
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Additional details
- Eprint ID
- 81142
- Resolver ID
- CaltechAUTHORS:20170905-132641863
- NASA
- HST-AR-13896
- NASA
- HST-AR-13888
- NASA
- HST-AR-13270
- NASA
- HST-AR-12836
- NASA
- HST-GO-14734
- NASA
- NAS 5-26555
- Caltech Carnegie Fellowship
- Caltech Moore Center for Theoretical Cosmology and Physics
- Samuel P. Langley PITT PACC Postdoctoral Fellowship
- Weiland Family Stanford Graduate Fellowship
- Alvin E. Nashman Fellowship
- NSF
- AST-1517226
- Space Telescope Science Institute
- Created
-
2017-09-05Created from EPrint's datestamp field
- Updated
-
2021-11-15Created from EPrint's last_modified field
- Caltech groups
- Moore Center for Theoretical Cosmology and Physics