The Dependence of the Galactic Star Formation Laws on Metallicity

TL;DR

This study models how metallicity influences star formation laws in galaxies by incorporating feedback from stellar winds, showing that higher metallicity leads to more efficient gas evacuation and reduced star formation efficiency.

Contribution

It introduces a metallicity-dependent feedback model that accurately reproduces observed star formation laws across various galaxy environments.

Findings

Higher metallicity increases stellar wind strength.

Metallicity affects the gas evacuation rate from protocluster clumps.

The model explains the observed scatter in star formation laws.

Abstract

We describe results from semi-analytical modelling of star formation in protocluster clumps of different metallicities. In this model, gravitationally bound cores form uniformly in the clump following a prescribed core formation efficiency per unit time. After a contraction timescale which is equal to a few times their free-fall times, the cores collapse into stars and populate the IMF. Feedback from the newly formed OB stars is taken into account in the form of stellar winds. When the ratio of the effective energy of the winds to the gravitational energy of the system reaches unity, gas is removed from the clump and core and star formation are quenched. The power of the radiation driven winds has a strong dependence on metallicity and it increases with increasing metallicity. Thus, winds from stars in the high metallicity models lead to a rapid evacuation of the gas from the protocluster clump and to a reduced star formation efficiency, as compared to their low metallicity counterparts. We derive the metallicity dependent star formation efficiency per unit time in this model as a function of the gas surface density Sigma_g. This is combined with the molecular gas fraction in order to derive the dependence of the surface density of star formation Sigma_SFR on Sigma_g. This feedback regulated model of star formation reproduces very well the observed star formation laws in galaxies extending from low gas surface densities up to the starburst regime. Furthermore, the results show a dependence of Sigma_SFR on metallicity over the entire range of gas surface densities, and can also explain part of the scatter in the observations.