Constraining Cosmic-ray Transport with Observations of the Circumgalactic Medium

Abstract

Recent theoretical studies predict that the circumgalactic medium (CGM) around low-redshift, L* galaxies could have substantial nonthermal pressure support in the form of cosmic rays. However, these predictions are sensitive to the specific model of cosmic-ray transport employed, which is theoretically and observationally underconstrained. In this work, we propose a novel observational constraint for calculating the lower limit of the radially-averaged, effective cosmic-ray transport rate, min eff. Under a wide range of assumptions (so long as cosmic rays do not lose a significant fraction of their energy in the galactic disk, regardless of whether the cosmic-ray pressure is important or not in the CGM), we demonstrate a well-defined relationship between min eff and three observable galaxy properties: the total hydrogen column density, the average star formation rate, and the gas circular velocity. We use a suite of FIRE-2 galaxy simulations with a variety of cosmic-ray transport physics to demonstrate that our analytic model of min eff is a robust lower limit of the true cosmic-ray transport rate. We then apply our new model to calculate min eff for galaxies in the COS-Halos sample, and confirm this already reveals strong evidence for an effective transport rate which rises rapidly away from the interstellar medium to values min eff 1030-31\, cm2\, s-1 (corresponding to anisotropic streaming velocities of v stream eff 1000\, km\, s-1) in the diffuse CGM, at impact parameters larger than 50-100\,kpc. We discuss how future observations can provide qualitatively new constraints in our understanding of cosmic rays in the CGM and intergalactic medium.