Magnetically Driven Outflows in a Starburst Environment

Abstract

We here investigate the possibility that the observed collimated outflows in luminous infrared galaxies (LIGs) and some Seyfert galaxies can be produced in a starburst (SB) environment. A nuclear disk can be quickly produced by gas infall during star formation in a rotating, stellar cluster. We find that massive nuclear SBs with core disk masses Md 108 - 109 M, and supernova rates SN 5 × 10-3 - 2 yr-1 (which are consistent with the SN values inferred from the observed non-thermal radio power in source candidates) may inject kinetic energies which are high enough to blow out directed flows from the accreting disk surface, within the SB lifetimes. In our models, the acceleration and collimation of the nuclear outflow are provided by magnetic fields anchored into the rotating SB-disk. The emerging outflow carries a kinetic power that is only a small fraction (a few percent) of the supernovae energy rate produced in the SB. Based on conditions determined from observed outflows and disks, we find that moderate disk magnetic fields ( 8 × 10-4 G) are able to accelerate the outflows up to the observed terminal velocities ( few 100 km s-1 in the case of the Seyfert galaxies, and 400 - 950 km s-1 in the case of the LIGs). The outflow is produced within a wind zone in the disk of radius 100 pc in the LIGs, and 10 pc in the Seyferts, with wind mass loss to disk accretion rate ratios Mw / Md 0.1 (where Md 100 M yr-1). The observation of rotating nuclear disks of gas within few 100 pc scales in source candidates like the LIG Arp 220, and magnetized outflows provide observational support for the picture drawn here.

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