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 H2 and HD. It is found that the cloud evolution is governed mainly by the initial central density (n c,0) and H2 abundance (x H2,0). In particular, the evolution of low-density filaments bifurcates at a threshold H2 abundance of x H2,cr 3 × 10-3, beyond which HD cooling overwhelms H2 cooling. The contraction of a low density filament with x H2, 0 x H2,cr is strongly decelerated when n c reaches a critical density of HD, and the filament is expected to fragment at 107 cm-3. The fragment mass is lowered to be ≈ 10M. In contrast, the contraction of a low density filament with x H2, 0 x H2,cr is regulated by H2 cooling. In this case, the fragment mass is as high as ≈ 102M. For a high-density filament, the cloud evolution is governed by H2 cooling. The fragmentation is not expected to take place until the cloud becomes opaque in H2 lines at n c,0 1012-13 cm-3, 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 10M or 102M, dependently on n c,0 and x H2,0.

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