The masses, structure and lifetimes of cold clouds in a high-resolution simulation of a low metallicity starburst

TL;DR

This study uses high-resolution simulations to analyze the properties, lifecycle, and disruption processes of cold gas clouds in a low metallicity starburst galaxy, revealing their mass distribution, structural relations, and short lifetimes.

Contribution

It provides a detailed analysis of cold cloud properties and lifecycles in a realistic galaxy simulation, highlighting rapid formation and disruption processes.

Findings

Cold clouds follow a power-law mass function with slope -1.78.

Cloud lifetimes are exponentially distributed with a 3.5 Myr e-folding time.

Cloud mass and size relate to lifetime, supporting rapid star formation cycles.

Abstract

We present an analysis of the cold gas phase in a low metallicity starburst generated in a high-resolution hydrodynamical simulation of a gas-rich dwarf galaxy merger as part of the GRIFFIN project. The simulations resolve (4 M$_\odot$ gas phase mass resolution, $\sim$ 0.1 pc spatial resolution) the multi-phase interstellar medium with a non-equilibrium chemical heating/cooling network at temperatures below $10^4$ K. Massive stars are sampled individually and interact with the ISM through the formation of HII regions and supernova explosions. In the extended starburst phase, the ISM is dominated by cold ($T_\mathrm{gas} < 300$ K) filamentary clouds with self-similar internal structures. The clouds have masses of $10^{2.6}$ - $10^{5.6}$ M$_\odot$ with a power law mass function, $dN/dM \propto M^\alpha$ with $\alpha = -1.78 (\pm 0.08)$. They also follow the Larson relations, in good agreement with observations. We trace the lifecycle of the cold clouds and find that they follow an exponential lifetime distribution and an e-folding time of $\sim$ 3.5 Myr. Clouds with peak masses below $10^4$ M$_\odot$ follow a power law relation with their average lifetime $\tau_\mathrm{life} \propto M^{0.3}_\mathrm{max}$ which flattens out for higher cloud masses at $ < 10$ Myr. A similar relation exists between cloud size at peak mass and lifetime. This simulation of the evolution of a realistic galactic cold cloud population supports the rapid formation and disruption of star-forming clouds by stellar radiation and supernovae on a timescale less than 10 Myr.