Small-scale dynamo action during the formation of the first stars and galaxies. I. The ideal MHD limit

TL;DR

This paper models how magnetic seed fields are amplified during the formation of the first stars and galaxies, highlighting the role of turbulence and small-scale dynamo processes in increasing magnetic field strength before disk formation.

Contribution

It introduces a semi-analytic model for magnetic field amplification during gravitational collapse, considering different turbulence regimes and their effects on magnetic saturation levels.

Findings

Magnetic fields can be substantially amplified before disk formation.

Saturation occurs after ~10^8 years in first star-forming halos.

Magnetic field strength may reach ~10^{-7} G in early halos, higher in first galaxies.

Abstract

We explore the amplification of magnetic seed fields during the formation of the first stars and galaxies. During gravitational collapse, turbulence is created from accretion shocks, which may act to amplify weak magnetic fields in the protostellar cloud. Numerical simulations showed that such turbulence is sub-sonic in the first star-forming minihalos, and highly supersonic in the first galaxies with virial temperatures larger than 10^4 K. We investigate the magnetic field amplification during the collapse both for Kolmogorov and Burgers-type turbulence with a semi-analytic model that incorporates the effects of gravitational compression and small-scale dynamo amplification. We find that the magnetic field may be substantially amplified before the formation of a disk. On scales of 1/10 of the Jeans length, saturation occurs after ~10^8 yr. Although the saturation behaviour of the small-scale dynamo is still somewhat uncertain, we expect a saturation field strength of the order ~10^{-7} n^{0.5} G in the first star-forming halos, with n the number density in cgs units. In the first galaxies with higher turbulent velocities, the magnetic field strength may be increased by an order of magnitude, and saturation may occur after 10^6 to 10^7 yr. In the Kolmogorov case, the magnetic field strength on the integral scale (i.e. the scale with most magnetic power) is higher due to the characteristic power-law indices, but the difference is less than a factor of 2 in the saturated phase. Our results thus indicate that the precise scaling of the turbulent velocity with length scale is of minor importance. They further imply that magnetic fields will be significantly enhanced before the formation of a protostellar disk, where they may change the fragmentation properties of the gas and the accretion rate.