Long-Lived Eccentricities in Accretion Disks
Abstract
Accretion disks can be eccentric: they support modes that are global and slowly precessing. But whether the modes remain trapped in the disk---and hence are long-lived---depends on conditions at the outer edge of the disk. Here we show that in disks with realistic boundaries, in which the surface density drops rapidly beyond a given radius, eccentric modes are trapped and hence long-lived. We focus on pressure-only disks around a central mass, and show how this result can be understood with the help of a simple second-order WKB theory. We show that the longest lived mode is the zero-node mode in which all of the disk's elliptical streamlines are aligned, and that this mode decays coherently on the viscous timescale of the disk. Hence such a mode, once excited, will live for the lifetime of the disk. It may be responsible for asymmetries seen in recent images of protoplanetary disks.
Cite
@article{arxiv.1906.05290,
title = {Long-Lived Eccentricities in Accretion Disks},
author = {Wing-Kit Lee and Adam M. Dempsey and Yoram Lithwick},
journal= {arXiv preprint arXiv:1906.05290},
year = {2019}
}
Comments
Submitted to ApJ. Comments are welcomed