English

Fast Winds Drive Slow Shells: A Model for the Circumgalactic Medium as Galactic Wind-Driven Bubbles

Astrophysics of Galaxies 2018-09-12 v2

Abstract

Successful models of the low redshift circumgalactic medium (CGM) must account for (1) a large amount of gas, (2) relatively slow gas velocities, (3) a high degree of metal enrichment, (4) the similar absorption properties around both star-forming and passive galaxies, and (5) the observationally inferred temperature and densities of the CGM gas. We show that galactic wind-driven bubbles can account for these observed properties. We develop a model describing the motion of bubbles driven by a hot, fast galactic wind characteristic of supernova energy injection. The bubble size grows slowly to hundreds of kiloparsecs over 5105-10 Gyr. For high star formation rates or high wind mass loading M˙w/M˙\dot M_w/\dot M_\star, the free-flowing hot wind, the shocked hot wind in the interior of the bubble, and the swept-up halo gas within the bubble shell can all radiatively cool and contribute to low-ionization state metal line absorption. We verify that if the free-flowing wind cools, the shocked wind does as well. We find effective mass loading factors of (Mw+Mswept)/M512(M_w+M_\mathrm{swept})/M_\star\sim5-12 as the bubbles sweep into the CGM. We predict cool gas masses, velocities, column densities, metal content, and absorption line velocities and linewidths of the bubble for a range of parameter choices. This picture can reproduce many of the COS-Halos and Keeney et al. (2017) observations of low-ionization state metal absorption lines around both star-forming and passive galaxies.

Keywords

Cite

@article{arxiv.1804.00741,
  title  = {Fast Winds Drive Slow Shells: A Model for the Circumgalactic Medium as Galactic Wind-Driven Bubbles},
  author = {Cassandra Lochhaas and Todd A. Thompson and Eliot Quataert and David H. Weinberg},
  journal= {arXiv preprint arXiv:1804.00741},
  year   = {2018}
}

Comments

28 pages, 13 figures, accepted to MNRAS

R2 v1 2026-06-23T01:12:06.456Z