Dust Emission as a Function of Stellar Population Age in the Nearby Galaxy M33

TL;DR

This study investigates how 8 micron dust emission correlates with stellar population age in galaxy M33, revealing that emission decreases with age and complicates star formation rate estimates.

Contribution

It demonstrates the age dependence of 8 micron dust emission in star clusters of M33, providing insights for more accurate star formation indicators.

Findings

8 micron luminosity per unit stellar mass decreases with cluster age

Large scatter in emission linked to dust absorption variability

Age dependence persists up to ~400 Myr

Abstract

Dust emission at 8 micron has been extensively calibrated as an indicator of current star formation rate for galaxies and ~kpc-size regions within galaxies. Yet, the exact link between the 8 micron emission and the young stellar populations in galaxies is still under question, as dust grains can be stochastically heated also by older field stars. In order to investigate this link, we have combined mid-infrared images from the Spitzer Space Telescope with a published star cluster candidates catalog for the Local Group galaxy M33. M33 is sufficiently close that the Spitzer's 8 micron images resolve individual regions of star formation. Star clusters represent almost-single-age stellar populations, which are significantly easier to model than more complex mixtures of stars. We find a decrease in the 8 micron luminosity per unit stellar mass as a function of age of the star clusters, with a large scatter that is consistent with varying fractions of stellar light absorbed by dust. The decrease and scatter both confirm findings based on more distant galaxies and are well described by simple models for the dust emission of a young stellar population. We conclude that the dust emission at 8 micron depends sensitively on the age of the stellar population, out to at least the oldest age analyzed here, ~400 Myr. This dependence complicates the use of the 8 micron emission as a star formation rate indicator, at least for small galactic regions and individual star forming regions. By leveraging the Spitzer legacy, this investigation paves the way for future explorations with the James Webb Space Telescope.