Supermassive Black Hole Formation at High Redshifts Through a Primordial Magnetic Field

Abstract

It has been proposed that primordial gas in early dark matter halos, with virial temperatures above 104 K, can avoid fragmentation and undergo rapid collapse, possibly resulting in a supermassive black hole (SMBH). This requires the gas to avoid cooling and to remain at temperatures near T=104 K. We show that this condition can be satisfied in the presence of a sufficiently strong primordial magnetic field, which heats the collapsing gas via ambipolar diffusion. If the field has a strength above B = 3.6 (comoving) nG, the collapsing gas is kept warm (T=104K) until it reaches the critical density ncrit=103 cm-3 at which the roto-vibrational states of H2 approach local thermodynamic equilibrium. H2-cooling then remains inefficient, and the gas temperature stays near 104K, even as it continues to collapse to higher densities. The critical magnetic field strength required to permanently suppress H2-cooling is somewhat higher than upper limit of approx. 2 nG from the cosmic microwave background (CMB). However, it can be realized in the rare (2-3)-sigma regions of the spatially fluctuating B-field; these regions contain a sufficient number of halos to account for the z=6 quasar BHs.