Coagulation and Fragmentation in molecular clouds. II. The opacity of the dust aggregate size distribution

TL;DR

This study models how dust coagulation and ice-mantle formation in molecular clouds influence dust opacity, revealing that aggregate growth affects near-IR and silicate feature strengths, with implications for interpreting observations.

Contribution

It provides a detailed calculation of dust opacities considering coagulation, ice-mantle effects, and aggregate porosity, extending previous collision models to observable properties.

Findings

Near-IR opacity and silicate feature increase with dust growth to micron sizes.

Porous aggregates prolong the silicate feature despite coagulation.

Sub-mm index  will rise if dust aggregates reach ~100m in size.

Abstract

The dust size distribution in molecular clouds can be strongly affected by ice-mantle formation and (subsequent) grain coagulation. Following previous work where the dust size distribution has been calculated from a state-of-the art collision model for dust aggregates that involves both coagulation and fragmentation (Paper I), the corresponding opacities are presented in this study. The opacities are calculated by applying the effective medium theory assuming that the dust aggregates are a mix of 0.1{\mu}m silicate and graphite grains and vacuum. In particular, we explore how the coagulation affects the near-IR opacities and the opacity in the 9.7{\mu}m silicate feature. We find that as dust aggregates grow to {\mu}m-sizes both the near-IR color excess and the opacity in the 9.7 {\mu}m feature increases. Despite their coagulation, porous aggregates help to prolong the presence of the 9.7{\mu}m feature. We find that the ratio between the opacity in the silicate feature and the near-IR color excess becomes lower with respect to the ISM, in accordance with many observations of dark clouds. However, this trend is primarily a result of ice mantle formation and the mixed material composition of the aggregates, rather than being driven by coagulation. With stronger growth, when most of the dust mass resides in particles of size 10{\mu}m or larger, both the near-IR color excess and the 9.7{\mu}m silicate feature significantly diminish. Observations at additional wavelengths, in particular in the sub-mm range, are essential to provide quantitative constraints on the dust size distribution within dense cores. Our results indicate that the sub-mm index {\beta} will increase appreciably, if aggregates grow to ~100{\mu}m in size.