The magnetic fields of starburst galaxies. I. Identification and characterization of the thermal polarization in the galactic disk and outflow

Abstract

Far-infrared polarized emission by means of magnetically aligned dust grains is an excellent tracer of the magnetic fields (B-fields) in the cold phase of the galactic outflows in starburst galaxies. We present a comprehensive study of the B-fields in three nearby (3.5-17.2 Mpc) starbursts (M82, NGC 253, and NGC 2146) at 5 pc-1.5 kpc resolutions using publicly available 53-890 μm imaging polarimetric observations with SOFIA/HAWC+, JCMT/POL-2, and ALMA. We find that the polarized spectral energy distributions (SEDs) of the full galaxies are dominated by the polarized SEDs of the outflows with dust temperatures of Td,outflowPI45 K and emissive index of βoutflowPI2.3. The disks are characterized by low Td,diskPI=[24,31] K and βdiskPI1. We show that disk- and outflow-dominated galaxies can be better distinguished by using polarized SEDs instead of total SEDs. We compute the 53-850 μm polarization spectrum of the disk and outflow and find that dust models of the diffuse ISM can reproduce the fairly constant polarization spectrum of the disk, Pdisk =1.20.5%. The dust models of heterogenous clouds and two temperature components are required to explain the polarization spectrum of the outflow (2-4% at 53 μm, 1% at 850 μm, and a minimum within 89-154 μm). We conclude that the polarized dust grains in the outflow arise from a dust population with higher dust temperature and emissivities than those from the total flux. The B-fields of the outflows have maximum extensions within 89-214 μm reaching heights of 4 kpc, and flatter polarized fluxes than total fluxes. The extension of the B-field permeating the circumgalactic medium increases with increasing the star formation rate.