The impact of cosmic rays on dynamical balance and disk-halo interaction in Lstar disk galaxies

TL;DR

This study uses high-resolution cosmological simulations to investigate how cosmic rays influence the gas dynamics at the disk-halo interface in L* galaxies, revealing their role in driving warm winds and altering gas phase distributions.

Contribution

The paper introduces a detailed simulation-based analysis of cosmic ray effects on disk-halo interactions, highlighting their influence on gas acceleration, phase structure, and outflow behavior in low-redshift galaxies.

Findings

CRs slowly accelerate warm gas

CRs suppress hot gas scale height

Warm-hot medium dominates the disk-halo interface

Abstract

Cosmic rays (CRs) are an important component in the interstellar medium (ISM), but their effect on the dynamics of the disk-halo interface (< 10 kpc from the disk) is still unclear. We study the influence of CRs on the gas above the disk with high-resolution FIRE-2 cosmological simulations of late-type Lstar galaxies at redshift around zero. We compare runs with and without CR feedback (with constant anisotropic diffusion around 3e29 cm^2/s and streaming). Our simulations capture the relevant disk halo interactions, including outflows, inflows, and galactic fountains. Extra-planar gas in all of the runs satisfies dynamical balance, where total pressure balances the weight of the overlying gas. While the kinetic pressure from non-uniform motion (>1-kpc scale) dominates in the midplane, thermal and bulk pressures (or CR pressure if included) take over at large heights. We find that with CR feedback, (1) the warm (1e4K) gas is slowly accelerated by CRs; (2) the hot (> 5e5K) gas scale height is suppressed; (3) the warm-hot (2e4-5e5K) medium becomes the most volume-filling phase in the disk-halo interface. We develop a novel conceptual model of the near-disk gas dynamics in low-redshift Lstar galaxies: With CRs, the disk-halo interface is filled with CR-driven warm winds and hot super-bubbles that are propagating into the CGM with a small fraction falling back to the disk. Without CRs, most outflows from hot superbubbles are trapped by the existing hot halo and gravity, so typically they form galactic fountains.