Effects of baryon removal on the structure of dwarf spheroidal galaxies

Arraki, Kenza S.; Klypin, Anatoly; More, Surhud; Trujillo-Gomez, Sebastian

doi:10.1093/mnras/stt2279

Cited by 99 publications

(107 citation statements)

References 116 publications

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“…D.1. Similar to Arraki et al (2014), the removal of baryons in NBF-50 produces a dramatic loss in dark matter density (and therefore mass within the 1 kpc and 3 kpc boundaries), although the mass loss is slightly under that found by Arraki et al possibly attributable to the instantaneous removal of the baryons here. The tidal model NTO-50 retains the central mass density of NRPS-50, and tracks it closely until the first perigalacticon.…”

Section: D1 Mass Evolutionsupporting

confidence: 72%

“…de Blok et al 2008;Walker & Peñarrubia 2011;Breddels & Helmi 2013) and, as the inner profile can alter the tidal evolution (Kazantzidis et al 2013), simulating the internal star formation is vitally important to understanding the evolution of a dwarf. In addition to the internal star formation changing its profile, the removal of gas also impacts the inner density (Arraki et al 2014) and the inclusion of this baryon loss may lead to a lower fraction of surviving dwarfs than expected from simulations that retain gas. In addition the metallicity evolution is intricately linked with the star formation history (and contributes towards its regulation through cooling), and with high-resolution studies of dwarf spheroidals now available (e.g.…”

Section: Introductionmentioning

confidence: 99%

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The post-infall evolution of a satellite galaxy

Nichols

Revaz

Jablonka

2015

A&A

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We describe a new method that only focuses on the local region surrounding an infalling dwarf in an effort to understand how the hot baryonic halo alters the chemodynamical evolution of dwarf galaxies. Using this method, we examine how a dwarf, similar to Sextans dwarf spheroidal, evolves in the corona of a Milky Way-like galaxy. We find that even at high perigalacticons the synergistic interaction between ram pressure and tidal forces transform a dwarf into a stream, suggesting that Sextans was much more massive in the past to have survived its perigalacticon passage. In addition, the large confining pressure of the hot corona allows gas that was originally at the outskirts to begin forming stars, initially forming stars of low metallicity compared to the dwarf evolved in isolation. This increase in star formation eventually allows a dwarf galaxy to form more metal rich stars compared to a dwarf in isolation, but only if the dwarf retains gas for a sufficiently long period of time. In addition, dwarfs that formed substantial numbers of stars post-infall have a slightly elevated [Mg/Fe] at high metallicity ([Fe/H] ∼ −1.5).

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Section: D1 Mass Evolutionsupporting

confidence: 72%

Section: Introductionmentioning

confidence: 99%

The post-infall evolution of a satellite galaxy

Nichols

Revaz

Jablonka

2015

A&A

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“…Indeed, analyses of stellar subpopulations within several dSphs indicate cored central density profiles [4,[59][60][61][62] (except for Draco [63]). Several studies using hydrodynamical simulations have suggested that baryonic physics -i.e., feedback from star formation and supernovae, as well as ram pressure and tidal stripping from the host halo -may induce dSph cores [64][65][66][67], while Ref. [68] found a smaller impact from baryonic effects.…”

Section: Self-interacting Dark Matter and Small Scale Structurementioning

confidence: 95%

Beyond collisionless dark matter: Particle physics dynamics for dark matter halo structure

2013

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Dark matter (DM) self-interactions have important implications for the formation and evolution of structure, from dwarf galaxies to clusters of galaxies. We study the dynamics of self-interacting DM via a light mediator, focusing on the quantum resonant regime where the scattering cross section has a non-trivial velocity dependence. While there are long-standing indications that observations of small scale structure in the Universe are not in accord with the predictions of collisionless DM, theoretical study and simulations of DM self-interactions have focused on parameter regimes with simple analytic solutions for the scattering cross section, with constant or classical velocity (and no angular) dependence. We devise a method that allows us to explore the velocity and angular dependence of self-scattering more broadly, in the strongly-coupled resonant and classical regimes where many partial modes are necessary for the achieving the result. We map out the entire parameter space of DM self-interactions -and implications for structure observations -as a function of the coupling and the DM and mediator masses. We derive a new analytic formula for describing resonant s-wave scattering. Finally, we show that DM self-interactions can be correlated with observations of Sommerfeld enhancements in DM annihilation through indirect detection experiments.

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“…43) are consistent with this expectation, with density profile slopes that are negligibly affected by feedback at the 0.5-kpc scale. On the other hand, high-resolution simulations of luminous satellites in the halo of Milky Way-like hosts do show reduced central dark matter densities from a combination of early feedback effects with ram pressure stripping and tidal heating by the host halo and disk, processes that can extract energy from the host galaxy's gravitational potential (50)(51)(52). Alternatively, Kuhlen et al (53) argue that the regulation of star formation by molecular hydrogen cooling may make the stellar content of galaxies highly stochastic at a halo mass as high as 10 10 M ⊙ (also ref.…”

Section: Solutions In Baryonic Physics?mentioning

confidence: 99%

Cold dark matter: Controversies on small scales

Weinberg

Bullock

Governato

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

420

346

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The cold dark matter (CDM) cosmological model has been remarkably successful in explaining cosmic structure over an enormous span of redshift, but it has faced persistent challenges from observations that probe the innermost regions of dark matter halos and the properties of the Milky Way's dwarf galaxy satellites. We review the current observational and theoretical status of these "small-scale controversies." Cosmological simulations that incorporate only gravity and collisionless CDM predict halos with abundant substructure and central densities that are too high to match constraints from galaxy dynamics. The solution could lie in baryonic physics: Recent numerical simulations and analytical models suggest that gravitational potential fluctuations tied to efficient supernova feedback can flatten the central cusps of halos in massive galaxies, and a combination of feedback and low star formation efficiency could explain why most of the dark matter subhalos orbiting the Milky Way do not host visible galaxies. However, it is not clear that this solution can work in the lowest mass galaxies, where discrepancies are observed. Alternatively, the small-scale conflicts could be evidence of more complex physics in the dark sector itself. For example, elastic scattering from strong dark matter self-interactions can alter predicted halo mass profiles, leading to good agreement with observations across a wide range of galaxy mass. Gravitational lensing and dynamical perturbations of tidal streams in the stellar halo provide evidence for an abundant population of low-mass subhalos in accord with CDM predictions. These observational approaches will get more powerful over the next few years.dark matter | cosmology | galaxy formation T he cold dark matter (CDM) hypothesis-that dark matter consists of a weakly interacting particle whose velocity dispersion in the early universe was too small to erase structure on a galactic or subgalactic scale-emerged in the early 1980s and quickly became a central element of the theory of cosmic structure formation. Influential early papers include Peebles' calculation of cosmic microwave background (CMB) anisotropies and the matter power spectrum (1), discussions of galaxy formation with particle dark matter by Bond et al. (2) and Blumenthal et al. (3,4), and Davis et al.'s (5) numerical simulations of galaxy clustering. By the mid-1990s, the simplest CDM model with scale-invariant primordial fluctuations and a critical matter density of ðΩ m = 1Þ had run afoul of multiple lines of observational evidence, including the shape of the galaxy power spectrum, estimates of the mean matter density from galaxy clusters and galaxy motions, the age of the universe inferred from estimates of the Hubble constant, and the amplitude of matter clustering extrapolated forward from the fluctuations measured in the CMB. Many variants on "canonical" CDM were proposed to address these challenges, and by the turn of the century, the combination of supernova evidence for cosmic acceleration and CMB evidence for ...

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Effects of baryon removal on the structure of dwarf spheroidal galaxies

Cited by 99 publications

References 116 publications

The post-infall evolution of a satellite galaxy

The post-infall evolution of a satellite galaxy

Beyond collisionless dark matter: Particle physics dynamics for dark matter halo structure

Cold dark matter: Controversies on small scales

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