The Stellar Initial Mass Function in Primordial Galaxies
Abstract
In the context of star formation through fragmentation of an extremely metal-deficient protogalactic cloud, the gravitational collapse of filamentary gas clouds is explored with 1D numerical hydrodynamics coupled with non-equilibrium chemistry of H and HD. It is found that the cloud evolution is governed mainly by the initial central density () and H abundance (). In particular, the evolution of low-density filaments bifurcates at a threshold H abundance of , beyond which HD cooling overwhelms H cooling. The contraction of a low density filament with is strongly decelerated when reaches a critical density of HD, and the filament is expected to fragment at cm. The fragment mass is lowered to be . In contrast, the contraction of a low density filament with is regulated by H cooling. In this case, the fragment mass is as high as . For a high-density filament, the cloud evolution is governed by H cooling. The fragmentation is not expected to take place until the cloud becomes opaque in H lines at cm, so that the fragment mass is reduced to 1-2 M. As a result, the stellar IMF could be bimodal and deficient in sub-solar mass stars, where the high mass peak is around or , dependently on and .
Cite
@article{arxiv.astro-ph/0201497,
title = {The Stellar Initial Mass Function in Primordial Galaxies},
author = {Fumitaka Nakamura and Masayuki Umemura},
journal= {arXiv preprint arXiv:astro-ph/0201497},
year = {2009}
}
Comments
10 pages, 6 figures, accepted by ApJ