Disk Heating: Comparing the Milky Way with Cosmological Simulations

2021 ◽

Author(s):

Myoungwon Jeon ◽

Volker Bromm ◽

Gurtina Besla ◽

Jinmi Yoon ◽

Yumi Choi

Keyword(s):

Milky Way ◽

Dwarf Galaxies ◽

Mass Resolution ◽

Explosion Energy ◽

High Carbon ◽

Cosmological Simulations ◽

Carbon Abundance ◽

The Absolute ◽

Zoom In

Abstract CEMP-no stars, a subset of carbon enhanced metal poor (CEMP) stars ($\rm [C/Fe]\ge 0.7$ and $\rm [Fe/H]\lesssim -1$) have been discovered in ultra-faint dwarf (UFD) galaxies, with Mvir ≈ 108 M⊙ and M* ≈ 103 − 104 M⊙ at z = 0, as well as in the halo of the Milky Way (MW). These CEMP-no stars are local fossils that may reflect the properties of the first (Pop III) and second (Pop II) generation of stars. However, cosmological simulations have struggled to reproduce the observed level of carbon enhancement of the known CEMP-no stars. Here we present new cosmological hydrodynamic zoom-in simulations of isolated UFDs that achieve a gas mass resolution of mgas ≈ 60 M⊙. We include enrichment from Pop III faint supernovae (SNe), with ESN = 0.6 × 1051 erg, to understand the origin of CEMP-no stars. We confirm that Pop III and Pop II stars are mainly responsible for the formation of CEMP and C-normal stars respectively. New to this study, we find that a majority of CEMP-no stars in the observed UFDs and the MW halo can be explained by Pop III SNe with normal explosion energy (ESN = 1.2 × 1051 erg) and Pop II enrichment, but faint SNe might also be needed to produce CEMP-no stars with $\rm [C/Fe]\gtrsim 2$, corresponding to the absolute carbon abundance of $\rm A(C)\gtrsim 6.0$. Furthermore, we find that while we create CEMP-no stars with high carbon ratio $\rm [C/Fe]\approx 3-4$, by adopting faint SNe, it is still challenging to reproduce CEMP-no stars with extreme level of carbon abundance of $\rm A(C)\approx 7.0-7.5$, observed both in the MW halo and UFDs.

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The mass of the Milky Way out to 100 kpc using halo stars

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa3984 ◽

2020 ◽

Author(s):

Alis J Deason ◽

Denis Erkal ◽

Vasily Belokurov ◽

Azadeh Fattahi ◽

Facundo A Gómez ◽

...

Keyword(s):

Distribution Function ◽

Mass Concentration ◽

Milky Way ◽

Function Analysis ◽

Large Magellanic Cloud ◽

Systematic Bias ◽

Cosmological Simulations ◽

Halo Stars ◽

Systematic Effects ◽

Mass Estimate

Abstract We use a distribution function analysis to estimate the mass of the Milky Way out to 100 kpc using a large sample of halo stars. These stars are compiled from the literature, and the vast majority ($\sim \! 98\%$) have 6D phase-space information. We pay particular attention to systematic effects, such as the dynamical influence of the Large Magellanic Cloud (LMC), and the effect of unrelaxed substructure. The LMC biases the (pre-LMC infall) halo mass estimates towards higher values, while realistic stellar halos from cosmological simulations tend to underestimate the true halo mass. After applying our method to the Milky Way data we find a mass within 100 kpc of M( < 100kpc) = 6.07 ± 0.29(stat.) ± 1.21(sys.) × 1011M⊙. For this estimate, we have approximately corrected for the reflex motion induced by the LMC using the Erkal et al. model, which assumes a rigid potential for the LMC and MW. Furthermore, stars that likely belong to the Sagittarius stream are removed, and we include a 5% systematic bias, and a 20% systematic uncertainty based on our tests with cosmological simulations. Assuming the mass-concentration relation for Navarro-Frenk-White haloes, our mass estimate favours a total (pre-LMC infall) Milky Way mass of M200c = 1.01 ± 0.24 × 1012M⊙, or (post-LMC infall) mass of M200c = 1.16 ± 0.24 × 1012 M⊙ when a 1.5 × 1011M⊙ mass of a rigid LMC is included.

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A dark matter disc in three cosmological simulations of Milky Way mass galaxies

Monthly Notices of the Royal Astronomical Society ◽

10.1111/j.1365-2966.2009.14757.x ◽

2009 ◽

Vol 397 (1) ◽

pp. 44-51 ◽

Cited By ~ 94

Author(s):

J. I. Read ◽

L. Mayer ◽

A. M. Brooks ◽

F. Governato ◽

G. Lake

Keyword(s):

Dark Matter ◽

Milky Way ◽

Cosmological Simulations

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Cold Dark Matter Substructure and the Heating of Galactic Disks

Symposium - International Astronomical Union ◽

10.1017/s0074180900207419 ◽

2003 ◽

Vol 208 ◽

pp. 391-392

Author(s):

Andreea S. Font ◽

Julio F. Navarro

Keyword(s):

Dark Matter ◽

Cold Dark Matter ◽

Milky Way ◽

Dark Matter Halo ◽

Stellar Disk ◽

Minor Role ◽

Galactic Disks ◽

Cosmological Simulations ◽

A Minor

We investigate recent suggestions that substructure in cold dark matter (CDM) halos has potentially destructive effects on galactic disks. N-body simulations of disk/bulge models of the Milky Way, embedded in a dark matter halo with substructure similar to that found in cosmological simulations, show that tides from substructure halos play only a minor role in the dynamical heating of the stellar disk. This suggests that substructure might not preclude CDM halos from being acceptable hosts of thin stellar disks.

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Cosmological simulations of the Milky Way

Proceedings of the International Astronomical Union ◽

10.1017/s1743921310008707 ◽

2009 ◽

Vol 5 (H15) ◽

pp. 193-193

Author(s):

Lucio Mayer

Keyword(s):

Milky Way ◽

Cosmological Simulations ◽

Low Mass

AbstractRecent simulations of forming low-mass galaxies suggests a strategy for obtaining realistic models of galaxies like the Milky-Way.

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Modelling the outskirts of galaxies in a cosmological context

Proceedings of the International Astronomical Union ◽

10.1017/s174392131601111x ◽

2016 ◽

Vol 11 (S321) ◽

pp. 69-71

Author(s):

Andrew P. Cooper

Keyword(s):

Surface Brightness ◽

Milky Way ◽

State Of The Art ◽

Mass Function ◽

Stellar Mass ◽

Current Data ◽

Cosmological Simulations ◽

Cosmological Context ◽

Profile Amplitude

AbstractCurrent data broadly support trends of galaxy surface brightness profile amplitude and shape with total stellar mass predicted by state-of-the-art ΛCDM cosmological simulations, although recent results show signs of interesting discrepancies, particularly for galaxies less massive than the Milky Way. Here I discuss how perhaps the largest contribution to such discrepancies can be inferred almost directly from how well a given model agrees with the observed present-day galaxy stellar mass function.

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On the Co-orbitation of Satellite Galaxies along the Great Plane of Andromeda: NGC 147, NGC 185, and Expectations from Cosmological Simulations

The Astrophysical Journal ◽

10.3847/1538-4357/ac2aa9 ◽

2021 ◽

Vol 923 (1) ◽

pp. 42

Author(s):

Marcel S. Pawlowski ◽

Sangmo Tony Sohn

Keyword(s):

Milky Way ◽

Detailed Comparison ◽

Satellite System ◽

Line Of Sight ◽

Proper Motions ◽

Velocity Correlation ◽

Cosmological Simulations ◽

Rotating Structure ◽

Motion Measurements ◽

Satellite Galaxies

Abstract Half of the satellite galaxies of Andromeda form a narrow plane termed the Great Plane of Andromeda (GPoA), and their line-of-sight velocities display a correlation reminiscent of a rotating structure. Recently reported first proper-motion measurements for the on-plane satellites NGC 147 and NGC 185 indicate that they indeed co-orbit along the GPoA. This provides a novel opportunity to compare the M31 satellite system to ΛCDM expectations. We perform the first detailed comparison of the orbital alignment of two satellite galaxies beyond the Milky Way with several hydrodynamical and dark-matter-only cosmological simulations (Illustris TNG50, TNG100, ELVIS, and PhatELVIS) in the context of the Planes of Satellite Galaxies Problem. In line with previous works, we find that the spatial flattening and line-of-sight velocity correlation are already in substantial tension with ΛCDM, with none of the simulated analogs simultaneously reproducing both parameters. Almost none (3%–4%) of the simulated systems contain two satellites with orbital poles as well aligned with their satellite plane as indicated by the most likely proper motions of NGC 147 and NGC 185. However, within current measurement uncertainties, it is common (≈70%) that the two best-aligned satellites of simulated systems are consistent with the orbital alignment. Yet, the chance that any two simulated on-plane satellites have as well-aligned orbital poles as observed is low (≈4%). We conclude that confirmation of the tight orbital alignment for these two objects via improved measurements, or the discovery of similar alignments for additional GPoA members, holds the potential to further raise the tension with ΛCDM expectations.

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NIHAO-UHD: The properties of MW-like stellar disks in high resolution cosmological simulations

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stz3241 ◽

2019 ◽

Cited By ~ 11

Author(s):

Tobias Buck ◽

Aura Obreja ◽

Andrea V Macciò ◽

Ivan Minchev ◽

Aaron A Dutton ◽

...

Keyword(s):

Milky Way ◽

General Structure ◽

Stellar Mass ◽

Scale Height ◽

Stellar Disk ◽

Galactic Disks ◽

Cosmological Simulations ◽

Hydrodynamical Simulations ◽

Single Exponential ◽

Scale Length

Abstract Simulating thin and extended galactic disks has long been a challenge in computational astrophysics. We introduce the NIHAO-UHD suite of cosmological hydrodynamical simulations of Milky Way mass galaxies and study stellar disk properties such as stellar mass, size and rotation velocity which agree well with observations of the Milky Way and local galaxies. In particular, the simulations reproduce the age-velocity dispersion relation and a multi-component stellar disk as observed for the Milky Way. Half of our galaxies show a double exponential vertical profile, while the others are well described by a single exponential model which we link to the disk merger history. In all cases, mono-age populations follow a single exponential whose scale height varies monotonically with stellar age and radius. The scale length decreases with stellar age while the scale height increases. The general structure of the stellar disks is already set at time of birth as a result of the inside-out and upside-down formation. Subsequent evolution modifies this structure by increasing both the scale length and height of all mono-age populations. Thus, our results put tight constraints on how much dynamical memory stellar disks can retain over cosmological timescales. Our simulations demonstrate that it is possible to form thin galactic disks in cosmological simulations provided there are no significant stellar mergers at low redshifts. Most of the stellar mass is formed in-situ with only a few percent ($\lesssim 5\%$) brought in by merging satellites at early times. Redshift zero snapshots and halo catalogues are publicly available.

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Live fast, die young: GMC lifetimes in the FIRE cosmological simulations of Milky Way mass galaxies

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa2116 ◽

2020 ◽

Vol 497 (3) ◽

pp. 3993-3999 ◽

Cited By ~ 5

Author(s):

Samantha M Benincasa ◽

Sarah R Loebman ◽

Andrew Wetzel ◽

Philip F Hopkins ◽

Norman Murray ◽

...

Keyword(s):

Star Formation ◽

Molecular Clouds ◽

Milky Way ◽

Giant Molecular Clouds ◽

Physical Processes ◽

Cosmological Simulations ◽

Initial Investigation ◽

Nearby Galaxies

ABSTRACT We present the first measurement of the lifetimes of giant molecular clouds (GMCs) in cosmological simulations at z = 0, using the Latte suite of FIRE-2 simulations of Milky Way (MW) mass galaxies. We track GMCs with total gas mass ≳105 M⊙ at high spatial (∼1 pc), mass (7100 M⊙), and temporal (1 Myr) resolution. Our simulated GMCs are consistent with the distribution of masses for massive GMCs in the MW and nearby galaxies. We find GMC lifetimes of 5–7 Myr, or 1–2 freefall times, on average, with less than 2 per cent of clouds living longer than 20 Myr. We find decreasing GMC lifetimes with increasing virial parameter, and weakly increasing GMC lifetimes with galactocentric radius, implying that environment affects the evolutionary cycle of GMCs. However, our GMC lifetimes show no systematic dependence on GMC mass or amount of star formation. These results are broadly consistent with inferences from the literature and provide an initial investigation into ultimately understanding the physical processes that govern GMC lifetimes in a cosmological setting.

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