Dust Destruction Rates and Lifetimes in the Magellanic Clouds

TL;DR

This study quantifies dust destruction rates and lifetimes in the Magellanic Clouds using supernova remnants, revealing shorter dust lifetimes compared to the Milky Way and implications for dust reconstitution in molecular clouds.

Contribution

It provides the first detailed estimates of dust lifetimes and destruction efficiencies in the Magellanic Clouds based on a complete SNR sample, highlighting environmental effects.

Findings

Dust lifetimes: 22-54 Myr for silicate, 30-72 Myr for carbon in MCs.

Dust destruction rates exceed injection rates, implying reconstitution in molecular clouds.

Shorter dust lifetimes in MCs compared to the Milky Way.

Abstract

The nature, composition, abundance, and size distribution of dust in galaxies is determined by the rate at which it is created in the different stellar sources and destroyed by interstellar shocks. Because of their extensive wavelength coverage, proximity, and nearly face-on geometry, the Magellanic Clouds (MCs) provide a unique opportunity to study these processes in great detail. In this paper we use the complete sample of supernova remnants (SNRs) in the MCs to calculate the lifetime and destruction efficiencies of silicate and carbon dust in these galaxies. We find dust lifetimes of 22 +- 13 Myr (30 +- 17 Myr) for silicate (carbon) grains in the LMC, and 54 +- 32 Myr (72 +- 43 Myr) for silicate (carbon) grains in the SMC. The significantly shorter lifetimes in the MCs, as compared to the Milky Way, are explained as the combined effect of their lower total dust mass, and the fact that the dust-destroying isolated SNe in the MCs seem to be preferentially occurring in regions with higher than average dust-to-gas (D2G) mass ratios. We also calculate the supernova rate and the current star formation rate in the MCs, and use them to derive maximum dust injection rates by asymptotic giant branch stars and core collapse supernovae. We find that the injection rates are an order of magnitude lower than the dust destruction rates by the SNRs. This supports the conclusion that, unless the dust destruction rates have been considerably overestimated, most of the dust must be reconstituted from surviving grains in dense molecular clouds. More generally, we also discuss the dependence of the dust destruction rate on the local D2G mass ratio, the ambient gas density and metallicity, as well as the application of our results to other galaxies and dust evolution models.