A spectral Galerkin method for the coupled Orr-Sommerfeld and induction equations for free-surface MHD

TL;DR

This paper introduces a spectral Galerkin method for solving coupled Orr-Sommerfeld and induction equations in free-surface MHD, achieving high accuracy and stability at large spectral orders, and analyzing the effects of magnetic Prandtl number on flow stability.

Contribution

The paper develops a stable, high-order spectral Galerkin scheme for coupled MHD stability equations, with efficient boundary condition implementation and validation against nonlinear energy growth.

Findings

Eigenvalue computations stable at spectral order p=3000

Roundoff errors are independent of spectral order at high p

Critical Reynolds number depends on magnetic Prandtl number Pm

Abstract

We develop and test spectral Galerkin schemes to solve the coupled Orr-Sommerfeld (OS) and induction equations for parallel, incompressible MHD in free-surface and fixed-boundary geometries. The schemes' discrete bases consist of Legendre internal shape functions, supplemented with nodal shape functions for the weak imposition of the stress and insulating boundary conditions. The orthogonality properties of the basis polynomials solve the matrix-coefficient growth problem, and eigenvalue-eigenfunction pairs can be computed stably at spectral orders at least as large as p = 3,000 with p-independent roundoff error. Accuracy is limited instead by roundoff sensitivity due to non-normality of the stability operators at large hydrodynamic and/or magnetic Reynolds numbers (Re, Rm > 4E4). In problems with Hartmann velocity and magnetic-field profiles we employ suitable Gauss quadrature rules to evaluate the associated exponentially weighted sesquilinear forms without error. An alternative approach, which involves approximating the forms by means of Legendre-Gauss-Lobatto (LGL) quadrature at the 2p - 1 precision level, is found to yield equal eigenvalues within roundoff error. As a consistency check, we compare modal growth rates to energy growth rates in nonlinear simulations and record relative discrepancy smaller than $ 1E-5 $ for the least stable mode in free-surface flow at Re = 3E4. Moreover, we confirm that the computed normal modes satisfy an energy conservation law for free-surface MHD with error smaller than 1E-6. The critical Reynolds number in free-surface MHD is found to be sensitive to the magnetic Prandtl number Pm, even at the Pm = O(1E-5) regime of liquid metals.