200 research outputs found
Stellar Feedback, AGN Feedback and Fluid Microphysics in Galaxy Evolution
Understanding how the baryonic physics affects the formation and evolution of galaxies is one of the most critical questions in modern astronomy. Significant progress in understanding stellar feedback and modeling them explicitly in simulations have made it possible to reproduce a wide range of observed galaxy properties. However, there are still various pieces of missing physics and uncertainties in galaxies of different mass range.
In this thesis, I will explore these missing pieces in baryonic physics on top of the Feedback in Realistic Environments (FIRE) stellar feedback in the cosmological hydrodynamic zoom-in simulations (FIRE-2 suite) and isolated galaxy simulations. These high-resolution simulations with FIRE physics capture multi-phase realistic interstellar medium (ISM) with gas cooling down to 10K, and star formations in dense clumps in giant molecular clouds. They are, therefore, an ideal tool for investigating the missing pieces in baryonic physics.
In the first part of the thesis, Chapter 2, I will focus on the discrete effects of stellar feedback like individual supernovae, hypernovae, and initial mass function (IMF) sampling in dwarfs (109-1010 M⊙). These discrete processes of stellar feedback can have maximum effects on the small galaxies without being averaged out. I will show that the discretization of supernovae (SNe) is absolutely necessary, while the effects from IMF sampling and hypernovae (HNe) is not apparent, due to the strong clustering nature of star formation.
In the second part of the thesis, Chapter 3-4, I will focus on fluid microphysics, exploring their effects on galaxy properties and their interplay with stellar feedback in sub-L* galaxies. I will demonstrate that, once the stellar feedback is explicitly implemented as FIRE stellar feedback model, fluid microphysics such as magnetic fields, conduction, and viscosity only have minor effects on the galaxy properties like star formation rate (SFR), phase structure, or outflows. Stellar feedback also strongly alters the amplifications and morphology of the magnetic fields, resulting in much more randomly-oriented field lines. However, despite the stellar feedback, the amplification of magnetic fields in ISM gas is primarily dominated by flux-freezing compression.
In the final part of my thesis, I focus on the massive cluster ellipticals of 1012-1014 M⊙, where the physical mechanisms that regulate the observation-inferred cooling flows are highly uncertain -- the classic "cooling flow problem". I showed that solutions in the literature not associated with an active galactic nucleus (AGN), including stellar feedback, the cosmic ray from stellar feedback, magnetic fields, conduction, and morphological quenching, cannot possibly quench the galaxies, mostly because of the insufficient energy and the limited size of the affected region. After ruling out the non-AGN feedback solutions to the cooling flow problem, I will go into the most accessible, and perhaps promising solution: "AGN feedback", exploring the generic classes of AGN feedback models proposed in the literature. I am going to show that enhancing turbulence and injecting cosmic ray are probably the most important aspects of AGN feedback in galaxy quenching. Since they provide non-thermal pressure support that stably suppresses the core density, they can stably reduce the cooling flows without overheating the galactic cores.</p
Feedback first: the surprisingly weak effects of magnetic fields, viscosity, conduction, and metal diffusion on galaxy formation
Using high-resolution simulations with explicit treatment of stellar feedback
physics based on the FIRE (Feedback in Realistic Environments) project, we
study how galaxy formation and the interstellar medium (ISM) are affected by
magnetic fields, anisotropic Spitzer-Braginskii conduction and viscosity, and
sub-grid metal diffusion from unresolved turbulence. We consider controlled
simulations of isolated (non-cosmological) galaxies but also a limited set of
cosmological "zoom-in" simulations. Although simulations have shown significant
effects from these physics with weak or absent stellar feedback, the effects
are much weaker than those of stellar feedback when the latter is modeled
explicitly. The additional physics have no systematic effect on galactic star
formation rates (SFRs) . In contrast, removing stellar feedback leads to SFRs
being over-predicted by factors of . Without feedback, neither
galactic winds nor volume filling hot-phase gas exist, and discs tend to
runaway collapse to ultra-thin scale-heights with unphysically dense clumps
congregating at the galactic center. With stellar feedback, a multi-phase,
turbulent medium with galactic fountains and winds is established. At currently
achievable resolutions and for the investigated halo mass range
, the additional physics investigated here (MHD,
conduction, viscosity, metal diffusion) have only weak (-level)
effects on regulating SFR and altering the balance of phases, outflows, or the
energy in ISM turbulence, consistent with simple equipartition arguments. We
conclude that galactic star formation and the ISM are primarily governed by a
combination of turbulence, gravitational instabilities, and feedback. We add
the caveat that AGN feedback is not included in the present work
But What About... Cosmic Rays, Magnetic Fields, Conduction, & Viscosity in Galaxy Formation
We present a suite of high-resolution cosmological simulations, using the
FIRE-2 feedback physics together with explicit treatment of magnetic fields,
anisotropic conduction and viscosity, and cosmic rays (CRs) injected by
supernovae (including anisotropic diffusion, streaming, adiabatic, hadronic and
Coulomb losses). We survey systems from ultra-faint dwarf (, ) through Milky Way
masses, systematically vary CR parameters (e.g. the diffusion coefficient
and streaming velocity), and study an ensemble of galaxy properties
(masses, star formation histories, mass profiles, phase structure,
morphologies). We confirm previous conclusions that magnetic fields,
conduction, and viscosity on resolved (pc) scales have small
effects on bulk galaxy properties. CRs have relatively weak effects on all
galaxy properties studied in dwarfs (, ), or at high redshifts (), for
any physically-reasonable parameters. However at higher masses () and , CRs can suppress star
formation by factors , given relatively high effective diffusion
coefficients . At lower
, CRs take too long to escape dense star-forming gas and lose energy to
hadronic collisions, producing negligible effects on galaxies and violating
empirical constraints from -ray emission. But around , CRs escape the galaxy and build up a
CR-pressure-dominated halo which supports dense, cool ( K) gas
that would otherwise rain onto the galaxy. CR heating (from collisional and
streaming losses) is never dominant.Comment: 35 pages, 23 figures. Updated to match published (MNRAS) versio
The failure of stellar feedback, magnetic fields, conduction, and morphological quenching in maintaining red galaxies
The quenching "maintenance'" and related "cooling flow" problems are
important in galaxies from Milky Way mass through clusters. We investigate this
in halos with masses , using
non-cosmological high-resolution hydrodynamic simulations with the FIRE-2
(Feedback In Realistic Environments) stellar feedback model. We specifically
focus on physics present without AGN, and show that various proposed "non-AGN"
solution mechanisms in the literature, including Type Ia supernovae, shocked
AGB winds, other forms of stellar feedback (e.g. cosmic rays), magnetic fields,
Spitzer-Braginskii conduction, or "morphological quenching" do not halt or
substantially reduce cooling flows nor maintain "quenched" galaxies in this
mass range. We show that stellar feedback (including cosmic rays from SNe)
alters the balance of cold/warm gas and the rate at which the cooled gas within
the galaxy turns into stars, but not the net baryonic inflow. If anything,
outflowing metals and dense gas promote additional cooling. Conduction is
important only in the most massive halos, as expected, but even at reduces inflow only by a factor (owing to
saturation effects and anisotropic suppression). Changing the morphology of the
galaxies only slightly alters their Toomre- parameter, and has no effect on
cooling (as expected), so has essentially no effect on cooling flows or
maintaining quenching. This all supports the idea that additional physics,
e.g., AGN feedback, must be important in massive galaxies.Comment: 16 pages, 12 figure
Discrete Effects in Stellar Feedback: Individual Supernovae, Hypernovae, and IMF Sampling in Dwarf Galaxies
Using high-resolution simulations from the FIRE-2 (Feedback In Realistic
Environments) project, we study the effects of discreteness in stellar feedback
processes on the evolution of galaxies and the properties of the interstellar
medium (ISM). We specifically consider the discretization of supernovae (SNe),
including hypernovae (HNe), and sampling the initial mass function (IMF). We
study these processes in cosmological simulations of dwarf galaxies with
stellar masses (halo masses ). We show that the discrete nature of individual SNe
(as opposed to a model in which their energy/momentum deposition is continuous
over time, similar to stellar winds) is crucial in generating a reasonable ISM
structure and galactic winds and in regulating dwarf stellar masses. However,
once SNe are discretized, accounting for the effects of IMF sampling on
continuous mechanisms such as radiative feedback and stellar mass-loss (as
opposed to adopting IMF-averaged rates) has weak effects on galaxy-scale
properties. We also consider the effects of rare HNe events with energies . The effects of HNe are similar to the effects of clustered
explosions of SNe -- which are already captured in our default simulation setup
-- and do not quench star formation (provided that the HNe do not dominate the
total SNe energy budget), which suggests that HNe yield products should be
observable in ultra-faint dwarfs today.Comment: 9 pages, 4 figure
Self-regulation of black hole accretion via jets in early protogalaxies
The early growth of black holes (BHs) in high-redshift galaxies is likely
regulated by their feedback on the surrounding gas. While radiative feedback
has been extensively studied, the role of mechanical feedback has received
comparatively less scrutiny to date. Here we use high-resolution parsec-scale
hydrodynamical simulations to study jet propagation and its effect on BH
accretion onto 100 BHs in the dense, low-metallicity gas
expected in early protogalaxies. As the jet propagates, it shocks the
surrounding gas and forms a jet cocoon. The cocoon consists of a
rapidly-cooling cold phase at the interface with the background gas and an
over-pressured subsonic phase of reverse shock-heated gas filling the cocoon
interior. We systematically vary the background gas density and temperature, BH
feedback efficiency, and the jet model. We found that the jet cocoon width
roughly follows a scaling derived by assuming momentum conservation in the jet
propagation direction, and energy conservation in the lateral directions.
Depending on the assumed gas and jet properties, the cocoon either stays
elongated out to a large radius or isotropizes before reaching the Bondi
radius, forming a nearly spherical bubble. Lower jet velocities and higher
background gas densities result in self-regulation to higher momentum fluxes
and elongated cocoons. In all cases, the outward momentum flux of the cocoon
balances the inward momentum flux of the inflowing gas near the Bondi radius,
which ultimately regulates BH accretion. The larger the distance the jet cocoon
reaches, the longer the variability timescale of the BH accretion rate.
Overall, the average accretion rate always remains below the Bondi rate, and
exceeds the Eddington rate only if the ambient medium is dense and cold, and/or
the jet is weak. We derive the combination of jet and ambient gas parameters
yielding super-Eddington growth.Comment: 16 pages, 11 figure
Accretion onto disk galaxies via hot and rotating CGM inflows
Observed accretion rates onto the Milky-Way and other local spirals fall
short of that required to sustain star formation for cosmological timescales. A
potential avenue for this unseen accretion is an inflow in the volume-filling
hot phase ( K) of the circumgalactic medium (CGM), as suggested by
some cosmological simulations. We derive an approximate axisymmetric analytic
solution of such hot CGM accretion flows, and validate it with hydrodynamic
simulations. We show that a hot inflow spins up as it approaches the galaxy,
while remaining hot, subsonic and quasi-spherical. At the radius of angular
momentum support ( kpc for the Milky-Way) the hot flow flattens into
a disk geometry and then cools from K to K at the
disk-halo interface. Cooling affects all hot gas, rather than just a subset of
individual gas clouds, implying that accretion via hot inflows does not rely on
local thermal instability in contrast with 'precipitation' models for galaxy
accretion. Prior to cooling and accretion the inflow completes radians of rotation, where is the
cooling time to free-fall time ratio in hot gas immediately outside the galaxy.
The ratio may thus govern the development of
turbulence and enhancement of magnetic fields in gas accreting onto
low-redshift spirals. We argue that accretion via hot inflows can explain the
observed truncation of nearby thin stellar disks at disk radii. We
also show that if rotating hot inflows are common in Milky-Way size disk
galaxies, as predicted, then signatures should be observable with X-ray
telescopes, kinetic SZ measurements, and FRB surveys.Comment: 19 pages, 11 figures, submitted to MNRA
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