Ashes of FIRE: Modeling Dust Grain Size Evolution in the Local Group with FIRE

TL;DR

This paper introduces a detailed dust grain size evolution model integrated into galaxy simulations, revealing how various dust processes influence dust properties and extinction curves in the Local Group.

Contribution

The study presents a novel discretized dust evolution model that tracks grain sizes and processes within galaxy simulations, predicting a bimodal grain size distribution and clarifying the roles of growth and destruction.

Findings

Dust abundance is mainly influenced by growth and destruction processes.

Coagulation affects extinction curve slopes and bump strengths.

Very small carbonaceous grains are not predicted due to rapid growth.

Abstract

We introduce a new, discretized grain size evolution model, incorporated into the GIZMO code and coupled with FIRE-3 stellar feedback and ISM physics, to investigate variations in dust abundance, chemical composition, and grain sizes observed in the Local Group. This model tracks the size evolution of specific dust species, and includes stellar production of dust, dust growth through gas-phase metal accretion, dust destruction by sputtering, SNe shocks, and astration, grain-grain collisional shattering and coagulation, and turbulent dust diffusion. Using idealized galaxy simulations, we test the dependence of MW dust properties on variations in each dust process and find that our model uniquely predicts a bimodal grain size distribution. This bimodality is due to our simulation's ability to resolve each dust process and where they occur in the ISM, unlike other works. We find that Local Group dust abundances are determined by dust growth and destruction, with little dependence on coagulation or shattering, explaining why models that do not include these processes can match abundance observations. We also find that variations in Local Group extinction curve slopes are determined by coagulation, with inefficient coagulation leading to steeper slopes. However, inefficient coagulation also results in stronger extinction curve bumps, which are not observed. We also do not predict a population of very small (${<}1$ nm) carbonaceous grains, required for MIR emission features, due to their rapid growth by accretion. These results highlight the possible necessity of ``top-down'' PAH formation from preexisting grains as a means to inhibit carbonaceous dust growth.