http://arxiv.org/abs/2112.04512
Magnetic fields play a vital role in numerous astrophysical processes such as star formation and the interstellar medium. In particular, their role in the formation and evolution of galaxies is not well understood. This paper presents high-resolution magnetohydrodynamic (MHD) simulations performed with GIZMO to investigate the effect of magnetic fields on primordial galaxy formation. Physical processes such as relevant gas physics (e.g., gas cooling and gas chemistry), star formation, stellar and supernova feedback, and chemical enrichment were considered in the simulations. The simulation results suggest that cosmic magnetic fields can be amplified from 1e-13 G to a few microgauss during cosmic structure evolution and galaxy formation. In the ideal MHD setting, in primordial galaxies at z>8, the magnetic energy is less than the thermal and kinetic energy, and therefore, magnetic fields hardly affect the gas dynamics and star formation in these galaxies. Specifically, the consideration of micro-physics properties such as metal diffusion, heat conduction, and viscosity in the MHD simulations, could increase the magnetic field strength. Notably, metal diffusion reduced gas cooling by decreasing the metallicity and thereby suppresses star formation in the primordial galaxies. As a result, the cosmic re-ionization driven by these primordial galaxies may be delayed.
H. Chiu and K. Chen
Fri, 10 Dec 21
88/94
Comments: submitted to ApJ, comments are welcome. (11 pages, 8 figures)