Godbillon-Vey Helicity and Magnetic Helicity in Magnetohydrodynamics

Abstract

The Godbillon-Vey invariant occurs in homology theory, and algebraic topology, when conditions for a co-dimension 1, foliation of a 3D manifold are satisfied. The magnetic Godbillon-Vey helicity invariant in magnetohydrodynamics (MHD) is a higher order helicity invariant that occurs for flows, in which the magnetic helicity density hm= A· B= A·(∇× A)=0, where A is the magnetic vector potential and B is the magnetic induction. This paper obtains evolution equations for the magnetic Godbillon-Vey field η= A× B/| A|2 and the Godbillon-Vey helicity density hgv=η·(∇×η) in general MHD flows in which either hm=0 or hm≠ 0. A conservation law for hgv occurs in flows for which hm=0. For hm≠ 0 the evolution equation for hgv contains a source term in which hm is coupled to hgv via the shear tensor of the background flow. The transport equation for hgv also depends on the electric field potential , which is related to the gauge for A, which takes its simplest form for the advected A gauge in which = A· u where u is the fluid velocity. An application of the Godbillon-Vey magnetic helicity to nonlinear force-free magnetic fields used in solar physics is investigated. The possible uses of the Godbillon-Vey helicity in zero helicity flows in ideal fluid mechanics, and in zero helicity Lagrangian kinematics of three-dimensional advection are discussed.