# But What About... Cosmic Rays, Magnetic Fields, Conduction, & Viscosity   in Galaxy Formation

**Authors:** Philip F. Hopkins (Caltech), T. K. Chan (UCSD), Shea Garrison-Kimmel, (Caltech), Suoqing Ji (Caltech), Kung-Yi Su (Caltech), Cameron B. Hummels, (Caltech), Dusan Keres (UCSD), Eliot Quataert (Berkeley), Claude-Andre, Faucher-Giguere (Northwestern)

arXiv: 1905.04321 · 2020-02-11

## TL;DR

This study uses high-resolution cosmological simulations to investigate the roles of magnetic fields, conduction, viscosity, and cosmic rays in galaxy formation, finding cosmic rays can significantly influence star formation in larger galaxies at lower redshifts.

## Contribution

It provides a comprehensive analysis of cosmic ray effects across different galaxy masses and redshifts, incorporating explicit magnetic and plasma physics in simulations.

## Key findings

- Magnetic fields, conduction, and viscosity have minimal effects on bulk galaxy properties.
- Cosmic rays can suppress star formation by factors of 2-4 in massive galaxies at low redshift.
- Cosmic rays build up in halos, supporting cool gas and affecting galaxy evolution.

## Abstract

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 ($M_{\ast}\sim 10^{4}\,M_{\odot}$, $M_{\rm halo}\sim 10^{9}\,M_{\odot}$) through Milky Way masses, systematically vary CR parameters (e.g. the diffusion coefficient $\kappa$ 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 ($\gtrsim 1\,$pc) scales have small effects on bulk galaxy properties. CRs have relatively weak effects on all galaxy properties studied in dwarfs ($M_{\ast} \ll 10^{10}\,M_{\odot}$, $M_{\rm halo} \lesssim 10^{11}\,M_{\odot}$), or at high redshifts ($z\gtrsim 1-2$), for any physically-reasonable parameters. However at higher masses ($M_{\rm halo} \gtrsim 10^{11}\,M_{\odot}$) and $z\lesssim 1-2$, CRs can suppress star formation by factors $\sim 2-4$, given relatively high effective diffusion coefficients $\kappa \gtrsim 3\times10^{29}\,{\rm cm^{2}\,s^{-1}}$. At lower $\kappa$, 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 $\gamma$-ray emission. But around $\kappa\sim 3\times10^{29}\,{\rm cm^{2}\,s^{-1}}$, CRs escape the galaxy and build up a CR-pressure-dominated halo which supports dense, cool ($T\ll 10^{6}$ K) gas that would otherwise rain onto the galaxy. CR heating (from collisional and streaming losses) is never dominant.

## Full text

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## Figures

113 figures with captions in the complete paper: https://tomesphere.com/paper/1905.04321/full.md

## References

221 references — full list in the complete paper: https://tomesphere.com/paper/1905.04321/full.md

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Source: https://tomesphere.com/paper/1905.04321