But what about...: cosmic rays, magnetic fields, conduction, and viscosity in galaxy formation

Hopkins, Philip F.; Chan, T. K.; Garrison-Kimmel, Shea; Ji, Suoqing; Su, Kung-Yi; Hummels, Cameron; Kereš, Dušan; Quataert, Eliot; Faucher-Giguère, Claude André

doi:10.1093/mnras/stz3321

Cited by 164 publications

(225 citation statements)

References 210 publications

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“…Observational evidence, including superthermal CO line widths and the size-line width relation observed within GMCs, suggest that turbulent motion dominates over thermal motion on physical scales comparable to cloud sizes (Larson 1981;Solomon et al 1987;Heyer & Brunt 2004; also see Heyer & Dame 2015). Numerical simulations of the star-forming ISM on galactic scales also find that the magnetic term is subdominant, typically reaching only50% of the kinetic term in the effective gas pressure Pakmor et al 2017;Su et al 2017;Hopkins et al 2020; also see observational evidence presented by Crutcher 1999;Falgarone et al 2008;Thompson et al 2019). Motivated by these findings, we assume in this work that turbulent motion represents the primary source of internal pressure in molecular gas, and treat all other contributions as subdominant.…”

Section: Internal Pressure In Molecular Gasmentioning

confidence: 94%

Dynamical Equilibrium in the Molecular ISM in 28 Nearby Star-forming Galaxies

Sun

Leroy

Ostriker

et al. 2020

ApJ

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We compare the observed turbulent pressure in molecular gas, P turb , to the required pressure for the interstellar gas to stay in equilibrium in the gravitational potential of a galaxy, P DE. To do this, we combine arcsecond resolution CO data from PHANGS-ALMA with multiwavelength data that trace the atomic gas, stellar structure, and star formation rate (SFR) for 28 nearby star-forming galaxies. We find that P turb correlates with-but almost always exceeds-the estimated P DE on kiloparsec scales. This indicates that the molecular gas is overpressurized relative to the large-scale environment. We show that this overpressurization can be explained by the clumpy nature of molecular gas; a revised estimate of P DE on cloud scales, which accounts for molecular gas self-gravity, external gravity, and ambient pressure, agrees well with the observed P turb in galaxy disks. We also find that molecular gas with cloud-scale »- P P k 10 K cm turb DE 5 B 3 in our sample is more likely to be self-gravitating, whereas gas at lower pressure it appears more influenced by ambient pressure and/or external gravity. Furthermore, we show that the ratio between P turb and the observed SFR surface density, S SFR , is compatible with stellar feedback-driven momentum injection in most cases, while a subset of the regions may show evidence of turbulence driven by additional sources. The correlation between S SFR and kpc-scale P DE in galaxy disks is consistent with the expectation from self-regulated star formation models. Finally, we confirm the empirical correlation between molecular-to-atomic gas ratio and kpc-scale P DE reported in previous works.

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Section: Internal Pressure In Molecular Gasmentioning

confidence: 94%

Dynamical Equilibrium in the Molecular ISM in 28 Nearby Star-forming Galaxies

Sun

Leroy

Ostriker

et al. 2020

ApJ

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“…However, neither the SFR history nor the present-day SFR is similar. The "m12i" FIRE halo has a factor of 10-12 higher SFR (see Figure 3 in Hopkins et al 2020) than the present-day SFR of M31 of 0.5 M e yr −1 (e.g., Kang et al 2009). We compare Project AMIGA to FIRE-2 simulations with two different sets of physical ingredients.…”

Section: Quantitative Comparison In the Cgm Variation Betweenmentioning

confidence: 99%

“…In Section 4, we derive the empirical properties of the CGM of M31, including how the column densities and velocities vary with R and Φ, the covering factors of the ions and how they change with R, and the metal and baryon masses of the CGM of M31. In Section 5, we discuss the results derived in Section 4 and compare them to observations from the COS-Halos survey (Tumlinson et al 2013;Werk et al 2014) and to state-of-the-art cosmological zoom-ins from, in particular, the Feedback in Realistic Environments (FIRE; Hopkins et al 2020) and the Figuring Out Gas and Galaxies In Enzo (FOGGIE; Peeples et al 2019) simulation projects. In Section 6, we summarize our main conclusions.…”

Section: Introductionmentioning

confidence: 99%

Project AMIGA: The Circumgalactic Medium of Andromeda*

Lehner

Berek

Howk

et al. 2020

ApJ

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Project AMIGA (Absorption Maps In the Gas of Andromeda) is a survey of the circumgalactic medium (CGM) of Andromeda (M31, R vir ;300 kpc) along 43 QSO sightlines at impact parameters 25 R569 kpc (25 at RR vir). We use ultraviolet absorption measurements of Si II, Si III, Si IV, C II, and C IV from the Hubble Space Telescope/Cosmic Origins Spectrograph and O VI from the Far Ultraviolet Spectroscopic Explorer to provide an unparalleled look at how the physical conditions and metals are distributed in the CGM of M31. We find that Si III and O VI have a covering factor near unity for R1.2 R vir and 1.9 R vir , respectively, demonstrating that M31 has a very extended ∼10 4-10 5.5 K ionized CGM. The metal and baryon masses of the 10 4-10 5.5 K CGM gas within R vir are 10 8 and 4×10 10 (Z/0.3 Z e) −1 M e , respectively. There is not much azimuthal variation in the column densities or kinematics, but there is with R. The CGM gas at R0.5 R vir is more dynamic and has more complicated, multiphase structures than at larger radii, perhaps a result of more direct impact of galactic feedback in the inner regions of the CGM. Several absorbers are projected spatially and kinematically close to M31 dwarf satellites, but we show that those are unlikely to give rise to the observed absorption. Cosmological zoom simulations of ∼L * galaxies have O VI extending well beyond R vir as observed for M31 but do not reproduce well the radial column density profiles of the lower ions. However, some similar trends are also observed, such as the lower ions showing a larger dispersion in column density and stronger dependence on R than higher ions. Based on our findings, it is likely that the Milky Way has a ∼10 4-10 5.5 K CGM as extended as for M31 and their CGM (especially the warm-hot gas probed by O VI) are overlapping.

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“…Nonthermal cosmic-ray pressure supports cold gas, enabling it to cool isochorically (Sharma et al 2010;Kempski & Quataert 2020), and may explain the inferred low densities of cold CGM gas. Cosmicray pressure also counteracts gravity and may prevent cold halo gas from accreting onto the galaxy (Hopkins et al 2020a). In some transport approximations, streaming cosmic rays transfer energy to the thermal gas and provide a source of heating.…”

Section: Introductionmentioning

confidence: 99%

The Impact of Cosmic Rays on Thermal Instability in the Circumgalactic Medium

Butsky

Fielding

Hayward

et al. 2020

ApJ

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Large reservoirs of cold (∼10 4 K) gas exist out to and beyond the virial radius in the circumgalactic medium (CGM) of all types of galaxies. Photoionization modeling suggests that cold CGM gas has significantly lower densities than expected by theoretical predictions based on thermal pressure equilibrium with hot CGM gas. In this work, we investigate the impact of cosmic-ray physics on the formation of cold gas via thermal instability. We use idealized three-dimensional magnetohydrodynamic simulations to follow the evolution of thermally unstable gas in a gravitationally stratified medium. We find that cosmic-ray pressure lowers the density and increases the size of cold gas clouds formed through thermal instability. We develop a simple model for how the cold cloud sizes and the relative densities of cold and hot gas depend on cosmic-ray pressure. Cosmic-ray pressure can help counteract gravity to keep cold gas in the CGM for longer, thereby increasing the predicted cold mass fraction and decreasing the predicted cold gas inflow rates. Efficient cosmic-ray transport, by streaming or diffusion, redistributes cosmicray pressure from the cold gas to the background medium, resulting in cold gas properties that are in between those predicted by simulations with inefficient transport and simulations without cosmic rays. We show that cosmic rays can significantly reduce galactic accretion rates and resolve the tension between theoretical models and observational constraints on the properties of cold CGM gas.

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But what about...: cosmic rays, magnetic fields, conduction, and viscosity in galaxy formation

Cited by 164 publications

References 210 publications

Dynamical Equilibrium in the Molecular ISM in 28 Nearby Star-forming Galaxies

Dynamical Equilibrium in the Molecular ISM in 28 Nearby Star-forming Galaxies

Project AMIGA: The Circumgalactic Medium of Andromeda*

The Impact of Cosmic Rays on Thermal Instability in the Circumgalactic Medium

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