Solar Nebula Magnetohydrodynamics
Abstract
The dynamical state of the solar nebula depends critically upon whether or not the gas is magnetically coupled. The presence of a subthermal field will cause laminar flow to break down into turbulence. Magnetic coupling, in turn, depends upon the ionization fraction of the gas. The inner most region of the nebula ( AU) is magnetically well-coupled, as is the outermost region ( AU). The magnetic status of intermediate scales ( AU) is less certain. It is plausible that there is a zone adjacent to the inner disk in which turbulent heating self-consistently maintains the requisite ionization levels. But the region adjacent to the active outer disk is likely to be magnetically ``dead.'' Hall currents play a significant role in nebular magnetohydrodynamics. Though still occasionally argued in the literature, there is simply no evidence to support the once standard claim that differential rotation in a Keplerian disk is prone to break down into shear turbulence by nonlinear instabilities. There is abundant evidence---numerical, experimental, and analytic---in support of the stabilizing role of Coriolis forces. Hydrodynamical turbulence is almost certainly not a source of enhanced turbulence in the solar nebula, or in any other astrophysical accretion disk.
Cite
@article{arxiv.astro-ph/9906317,
title = {Solar Nebula Magnetohydrodynamics},
author = {Steven A. Balbus and John F. Hawley},
journal= {arXiv preprint arXiv:astro-ph/9906317},
year = {2009}
}
Comments
19 pages, LaTEX, ISSI Space Sciences Series No.9