NIHAO III: The constant disc gas mass conspiracy

TL;DR

This study reveals that galactic disc gas masses reach a steady state influenced by halo properties, independent of stellar feedback, simplifying galaxy formation models.

Contribution

It demonstrates that the constant gas mass in galactic discs results from shared halo gas profiles, unaffected by feedback, and identifies key dependencies on halo spin and mass.

Findings

Disc gas mass reaches a steady state lasting several Gyr.

Gas mass depends on halo spin and virial mass, not feedback.

A break in the M_gas–M_200 relation corresponds to observed galaxy properties.

Abstract

We show that the cool gas masses of galactic discs reach a steady state that lasts many Gyr after their last major merger in cosmological hydrodynamic simulations. The mass of disc gas, M$_{\rm gas}$, depends upon a galaxy halo's spin and virial mass, but not upon stellar feedback. Halos with low spin have high star formation efficiency and lower disc gas mass. Similarly, lower stellar feedback leads to more star formation so the gas mass ends up nearly the same irregardless of stellar feedback strength. Even considering spin, the M$_{\rm gas}$ relation with halo mass, M$_{200}$ only shows a factor of 3 scatter. The M$_{\rm gas}$--M$_{200}$ relation show a break at M$_{200}$=$2\times10^{11}$ M$_\odot$ that corresponds to an observed break in the M$_{\rm gas}$--M$_\star$ relation. The constant disc mass stems from a shared halo gas density profile in all the simulated galaxies. In their outer regions, the profiles are isothermal. Where the profile rises above $n=10^{-3}$ cm$^{-3}$, the gas readily cools and the profile steepens. Inside the disc, rotation supports gas with a flatter density profile except where supernova explosions disrupt the disc. Energy injection from stellar feedback also provides pressure support to the halo gas to prevent runaway cooling flows. The resulting constant gas mass makes simpler models for galaxy formation possible, either using a "bathtub" model for star formation rates or when modeling chemical evolution.