Magnetic fields in the formation of the first stars.--II Results

TL;DR

This study uses advanced simulations to explore how magnetic fields influence the formation of the first stars, revealing that magnetic fields suppress low-mass star formation and lead to a top-heavy initial mass function.

Contribution

It introduces a new method for tracking kinematic magnetic fields and demonstrates their significant impact on Population III star formation in cosmological simulations.

Findings

Magnetic fields approach energy equipartition at high densities.

Magnetic fields suppress low-mass star formation, favoring massive stars.

Simulations show magnetic effects lead to a top-heavy initial mass function.

Abstract

Beginning with cosmological initial conditions at z=100, we simulate the effects of magnetic fields on the formation of Population III stars and compare our results with the predictions of Paper I. We use Gadget-2 to follow the evolution of the system while the field is weak. We introduce a new method for treating kinematic fields by tracking the evolution of the deformation tensor. The growth rate in this stage of the simulation is lower than expected for diffuse astrophysical plasmas, which have a very low resistivity (high magnetic Prandtl number); we attribute this to the large numerical resistivity in simulations, corresponding to a magnetic Prandtl number of order unity. When the magnetic field begins to be dynamically significant in the core of the minihalo at z=27, we map it onto a uniform grid and follow the evolution in an adaptive mesh refinement, MHD simulation in Orion2. The nonlinear evolution of the field in the Orion2 simulation violates flux-freezing and is consistent with the theory proposed by Xu & Lazarian. The fields approach equipartition with kinetic energy at densities ~ 10^10 - 10^12 cm^-3. When the same calculation is carried out in Orion2 with no magnetic fields, several protostars form, ranging in mass from ~ 1 to 30 M_sol with magnetic fields, only a single ~ 30 M_sol protostar forms by the end of the simulation. Magnetic fields thus suppress the formation of low-mass Pop III stars, yielding a top-heavy Pop III IMF and contributing to the absence of observed Pop III stars.