English

Large-scale-vortex dynamos in planar rotating convection

Fluid Dynamics 2017-03-01 v2 Earth and Planetary Astrophysics Solar and Stellar Astrophysics Geophysics

Abstract

Several recent studies have demonstrated how large-scale vortices may arise spontaneously in rotating planar convection. Here we examine the dynamo properties of such flows in rotating Boussinesq convection. For moderate values of the magnetic Reynolds number (100Rm550100 \lesssim Rm \lesssim 550, with RmRm based on the box depth and the convective velocity), a large-scale (i.e. system-size) magnetic field is generated. The amplitude of the magnetic energy oscillates in time, nearly out of phase with the oscillating amplitude of the large-scale vortex. The large-scale vortex is disrupted once the magnetic field reaches a critical strength, showing that these oscillations are of magnetic origin. The dynamo mechanism relies on those components of the flow that have length scales lying between that of the large-scale vortex and the typical convective cell size; smaller-scale flows are not required. The large-scale vortex plays a crucial role in the magnetic induction despite being essentially two-dimensional; we thus refer to this dynamo as a large-scale-vortex dynamo. For larger magnetic Reynolds numbers, the dynamo is small scale, with a magnetic energy spectrum that peaks at the scale of the convective cells. In this case, the small-scale magnetic field continuously suppresses the large-scale vortex by disrupting the correlations between the convective velocities that allow it to form. The suppression of the large-scale vortex at high RmRm therefore probably limits the relevance of the large-scale-vortex dynamo to astrophysical objects with moderate values of RmRm, such as planets. In this context, the ability of the large-scale-vortex dynamo to operate at low magnetic Prandtl numbers is of great interest.

Keywords

Cite

@article{arxiv.1607.00824,
  title  = {Large-scale-vortex dynamos in planar rotating convection},
  author = {Céline Guervilly and David W. Hughes and Chris A. Jones},
  journal= {arXiv preprint arXiv:1607.00824},
  year   = {2017}
}

Comments

28 pages, 17 figures, accepted for publication in J. Fluid Mech

R2 v1 2026-06-22T14:42:25.061Z