English

Instability-driven interfacial dynamo in protoneutron stars

Solar and Stellar Astrophysics 2011-10-06 v1 Fluid Dynamics

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 η\eta and turbulent vorticity α\alpha, 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 α\alpha, η\eta, and shear are coincident and the magnetic diffusivity is isotropic. In contrast, when the jumps in η\eta and α\alpha are situated away from the shear layer, self-sustained growth is possible for P49.8P\lesssim 49.8 ms (if the velocity shear is located at 0.3R0.3R) or P83.6P\lesssim 83.6 ms (if the velocity shear is located at 0.6R0.6R). This translates into stronger shear and/or α\alpha-effect than in the Sun. Self-sustained growth is also possible if the magnetic diffusivity if anisotropic, through the Ω×J{\bf{\Omega}}\times{\bf{J}} effect, even when the α\alpha, η\eta, 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

R2 v1 2026-06-21T18:44:35.918Z