Modelling the supernova-driven ISM in different environments
Abstract
We use hydrodynamical simulations in a periodic box to model the impact of supernova (SN) explosions on the multi-phase interstellar medium (ISM) for initial densities cm and SN rates Myr. We include radiative cooling, diffuse heating, and the formation of molecular gas using a chemical network. The SNe explode either at random positions, at density peaks, or both. We further present a model combining thermal energy for resolved and momentum input for unresolved SNe. Random driving at high SN rates results in hot gas ( K) filling % of the volume. This gas reaches high pressures ( K cm) due to the combination of SN explosions in the hot, low density medium and confinement in the periodic box. These pressures move the gas from a two-phase equilibrium to the single-phase, cold branch of the cooling curve. The molecular hydrogen dominates the mass (%), residing in small, dense clumps. Such a model might resemble the dense ISM in high-redshift galaxies. Peak driving results in huge radiative losses, producing a filamentary ISM with virtually no hot gas, and a small molecular hydrogen mass fraction (%). Varying the ratio of peak to random SNe yields ISM properties in between the two extremes, with a sharp transition for equal contributions. The velocity dispersion in HI remains km s in all cases. For peak driving the velocity dispersion in H can be as high as km s due to the contribution from young, embedded SN remnants.
Cite
@article{arxiv.1411.0009,
title = {Modelling the supernova-driven ISM in different environments},
author = {A. Gatto and S. Walch and M. -M. Mac Low and T. Naab and P. Girichidis and S. C. O. Glover and R. Wünsch and R. S. Klessen and P. C. Clark and C. Baczynski and T. Peters and J. P. Ostriker and J. C. Ibáñez-Mejía and S. Haid},
journal= {arXiv preprint arXiv:1411.0009},
year = {2015}
}
Comments
19 pages, 12 figures, 2 tables. Accepted for publication in MNRAS. Minor revisions to match published version