On the Timescale for Star Formation in Galaxies

TL;DR

This paper investigates the relationship between star formation timescales and dynamical timescales in galaxies, finding correlations but no simple linear relationship, and emphasizes the complexity of star formation processes.

Contribution

It compares multiple dynamical timescales with observed star formation timescales in nearby galaxies, highlighting non-linear correlations and the influence of GMC lifetimes.

Findings

All three dynamical timescales correlate with star formation timescale.

Correlations are non-linear and affected by systematic uncertainties.

GMC lifetime increases toward galaxy centers.

Abstract

The timescale for star formation, a measure of how quickly neutral gas is being converted to stars, is considerably longer than typical dynamical timescales associated with a galactic disk. For purposes of modeling galaxy evolution, however, it would be extremely attractive if the star formation timescale were proportional to an easily derived dynamical timescale. We compare estimates of the star formation timescale within nearby galaxies, based on the work of Leroy et al. (2008) and existing BIMA SONG CO data, with three simple forms of the dynamical time: the orbital time, the free-fall time at the midplane density, and the disk Jeans time (the growth time for gravitational instabilities in a disk). When taking into account the gravity of the stellar disk in an approximate way, all three timescales show correlations with the star formation timescale, though none of the correlations can be accurately described as linear. Systematic errors in estimating appropriate gas masses and the stellar velocity dispersion may obscure an underlying correlation, but we focus instead on a model where the timescale for H_2 formation from HI is decoupled from the timescale for star formation from H_2. The Jeans time correlates well with the first of these timescales, but the relationship is still non-linear, and requires a characteristic GMC lifetime that increases toward galaxy centers.