The opacity limit
Abstract
The opacity limit is an important concept in star formation: isothermal collapse cannot proceed without limit, because eventually cooling radiation is trapped and the temperature rises quasi-adiabatically, setting a minimum Jeans mass . Various works have considered this scenario and derived expressions for , generally in normal star-forming conditions, but with conflicting results about the scaling with ambient conditions and material properties. We derive expressions for the thermal evolution of dust-cooled collapsing gas clumps in various limiting cases, given a general ambient radiation field (, ) and a general power-law dust opacity law . By accounting for temperature evolution self-consistently we rule out a previously-proposed regime in which the adiabatic transition occurs while the core is still optically-thin. If the radiation field is weak or dust opacity is small, is insensitive to dust properties/abundance (), but if the radiation field is strong and dust is abundant it scales . This could make the IMF less bottom-heavy in dust-rich and/or radiation-dense environments, e.g. galactic centers, starburst galaxies, massive high- galaxies, and proto-star clusters that are already luminous.
Cite
@article{arxiv.2308.16268,
title = {The opacity limit},
author = {Michael Y. Grudić and Philip F. Hopkins},
journal= {arXiv preprint arXiv:2308.16268},
year = {2023}
}
Comments
To be submitted to the Open Journal of Astrophysics. Comments welcome