The Impact of HD Cooling on the Formation of the First Stars

TL;DR

This study uses numerical simulations to assess how HD cooling influences the formation and characteristics of the first stars, revealing its significance mainly in low-mass halos and ionized environments.

Contribution

It implements non-equilibrium HD chemistry in simulations and compares star formation in halos with and without ionization, highlighting HD cooling's role in early star formation.

Findings

HD cooling is significant in low-mass halos, reducing star mass by a factor of ~6.

In ionized halos, HD cooling lowers temperatures but does not significantly change stellar masses.

HD cooling dominates over H2 cooling in certain density ranges, but not at higher densities.

Abstract

We use numerical simulations to investigate the importance of HD formation and cooling on the first generation of metal-free stars in a LCDM cosmology. We have implemented and tested non-equilibrium HD chemistry in an adaptive mesh refinement simulation code and applied it to two situations. (1) It is first applied to the formation of 10^5 - 10^6 Msun halos which form in the absence of any ionizing source. We show, in agreement with previous work, that HD cooling is of only marginal importance for most halos; however, we find that for the lowest mass halos, HD cooling can equal or surpass the H2 cooling rate. This leads to a population of stars formed in halos with effective HD cooling that are less massive by a factor of ~6 compared to halos dominated by H2 cooling. (2) In the second part of the paper, we ionize the halos in order to explore the impact of HD cooling in the presence of an ample population of free electrons. This leads to cooler temperatures (due to the electron- catalyzed production of H2) and somewhat lower resulting proto-stellar mass. Adding HD chemistry lowers the temperature further, to the level of the CMB. We find that HD cooling dominates over H2 cooling in the density range 10^2 cm^-3 to 10^6 cm^-3, but above this density, the temperature rises and H2 cooling dominates again. Because of this, the accretion rate on to the protostar is almost the same as in the H2 case (at least for accreted masses below 50-100 Msun), therefore we argue that HD cooling in ionized halos will probably not result in a population of significantly lower mass stars.