Instability-driven interfacial dynamo in protoneutron stars
Abstract
The existence of a tachocline in the Sun has been proven by helioseismology. It is unknown whether a similar shear layer, widely regarded as the seat of magnetic dynamo action, also exists in a protoneutron star. Sudden jumps in magnetic diffusivity and turbulent vorticity , for example at the interface between the neutron-finger and convective zones, are known to be capable of enhancing mean-field dynamo effects in a protoneutron star. Here we apply the well-known, plane-parallel, MacGregor-Charbonneau analysis of the Solar interfacial dynamo to the protoneutron star problem and calculate the growth rate analytically under a range of conditions. It is shown that, like the Solar dynamo, it is impossible to achieve self-sustained growth if the discontinuities in , , and shear are coincident and the magnetic diffusivity is isotropic. In contrast, when the jumps in and are situated away from the shear layer, self-sustained growth is possible for ms (if the velocity shear is located at ) or ms (if the velocity shear is located at ). This translates into stronger shear and/or -effect than in the Sun. Self-sustained growth is also possible if the magnetic diffusivity if anisotropic, through the effect, even when the , , and shear discontinuities are coincident.
Keywords
Cite
@article{arxiv.1108.0221,
title = {Instability-driven interfacial dynamo in protoneutron stars},
author = {Alpha Mastrano and Andrew Melatos},
journal= {arXiv preprint arXiv:1108.0221},
year = {2011}
}
Comments
14 pages, 5 figures, 1 table