Black hole formation in primordial galaxies: chemical and radiative conditions

TL;DR

This paper investigates the cooling mechanisms in primordial galaxies, showing that despite high optical depths, atomic hydrogen transitions enable effective cooling, influencing galaxy collapse and potential star formation.

Contribution

It provides a detailed analysis of Lyman-Alpha photon trapping effects and identifies alternative atomic hydrogen cooling pathways in primordial galaxy environments.

Findings

Lyman-Alpha cooling remains effective despite high optical depth.

Molecular hydrogen dissociation cools gas to about 5000 K at high densities.

Gas evolution is nearly isothermal, affecting fragmentation potential.

Abstract

In massive primordial galaxies, the gas may directly collapse and form a single central massive object if cooling is suppressed. Line cooling by molecular hydrogen can be suppressed in the presence of a strong soft-ultraviolet radiation field, but the role played by other cooling mechanisms is less clear. In optically thin gas, Lyman-Alpha cooling can be very effective, maintaining the gas temperature below 10^4 K over many orders of magnitude in density. However, the large neutral hydrogen column densities present in primordial galaxies render them highly optically thick to Lyman-Alpha photons. In this letter, we examine in detail the effects of the trapping of these Lyman-Alpha photons on the thermal and chemical evolution of the gas. We show that despite the high optical depth in the Lyman series lines, cooling is not strongly suppressed, and proceeds via other atomic hydrogen transitions, in particular the 2s-1s and the 3-2 transitions. At densities larger than 10^9 cm^{-3}, collisional dissociation of molecular hydrogen becomes the dominant cooling process and decreases the gas temperature to about 5000 K. The gas temperature evolves with density as $T \propto \rho^{\gamma_{\rm eff} - 1}$, with $\gamma_{\rm eff} = 0.97-0.98$. The evolution is thus very close to isothermal, and so fragmentation is possible, but unlikely to occur during the initial collapse. However, after the formation of a massive central object, we expect that later-infalling, higher angular momentum material will form an accretion disk that may be unstable to fragmentation, which may give rise to star formation with a top-heavy IMF.