Accretion onto a Primordial Protostar

Abstract

We present a three-dimensional numerical simulation that resolves the formation process of a Population III star down to a scale of ~100 AU. The simulation is initialized on the scale of a dark matter halo of mass ~10^6 M_sun that virializes at z~20. It then follows the formation of a fully-molecular central core, and traces the accretion from the diffuse dust-free cloud onto the protostellar core for as long as ~10^4 yr, at which time the core has grown to ~50 M_sun. We find that the accretion rate starts very high, ~0.1 M_sun yr^-1, and declines rapidly thereafter approaching a power-law temporal scaling. Asymptotically, at times t > 10^3 yr after core formation, the stellar mass grows approximately as M_star=20 M_sun (t/10^3 yr)^0.4. Earlier on, accretion is faster with M_star \propto t^0.75. By extrapolating this growth over the full lifetime of very massive stars, t~3x10^6 yr, we obtain the conservative upper limit M_star < 500 M_sun. The actual stellar mass is, however, likely to be significantly smaller than this mass limit due to radiative and mechanical feedback from the protostar.