Stellar winds and photoionization in a spiral arm

TL;DR

This study uses high-resolution simulations to compare the effects of stellar winds and photoionization in a spiral arm, finding that photoionization is the dominant feedback mechanism influencing cloud disruption and star formation.

Contribution

It introduces a new method for modeling momentum-driven stellar winds in galaxy simulations and assesses their impact relative to photoionization in a spiral arm context.

Findings

Photoionization dominates cloud disruption and star formation regulation.

Stellar winds produce small cavities and have minimal impact on cloud statistics.

Winds influence the distribution of star formation among low- and high-mass sinks.

Abstract

The role of different stellar feedback mechanisms in giant molecular clouds is not well understood. This is especially true for regions with many interacting clouds as would be found in a galactic spiral arm. In this paper, building on previous work by Bending et al., we extract a $500\times500\times100$ pc section of a spiral arm from a galaxy simulation. We use smoothed particle hydrodynamics (SPH) to re-simulate the region at higher resolution (1 M$_\odot$ per particle). We present a method for momentum-driven stellar winds from main sequence massive stars, and include this with photoionization, self-gravity, a galactic potential, and ISM heating/cooling. We also include cluster-sink particles with accretion radii of 0.78 pc to track star/cluster formation. The feedback methods are as robust as previous models on individual cloud scales (e.g. Dale et al.). We find that photoionization dominates the disruption of the spiral arm section, with stellar winds only producing small cavities (at most $\sim$ 30 pc). Stellar winds do not affect the resulting cloud statistics or the integrated star formation rate/efficiency, unlike ionization, which produces more stars, and more clouds of higher density and higher velocity dispersion compared to the control run without feedback. Winds do affect the sink properties, distributing star formation over more low-mass sinks ($\sim 10^2$ M$_\odot$) and producing fewer high-mass sinks ($\sim 10^3$ M$_\odot$). Overall, stellar winds play at best a secondary role compared to photoionization, and on many measures, they have a negligible impact.