Conservative regularization of compressible dissipationless two-fluid plasmas

Abstract

This paper extends our earlier approach [cf. Phys. Plasmas 17, 032503 (2010), 23, 022308 (2016)] to obtaining a priori bounds on enstrophy in neutral fluids (R-Euler) and ideal magnetohydrodynamics (R-MHD). This results in a far-reaching local, three-dimensional, non-linear, dispersive generalization of a KdV-type regularization to compressible/incompressible dissipationless two-fluid plasmas and models derived therefrom (quasi-neutral, Hall and ideal MHD). It involves the introduction of vortical and magnetic `twirl' terms λl2 ( wl + qlml B) × (∇ × wl) in the ion/electron velocity equations (l = i,e) where wl = ∇ × vl are vorticities. The cut-off lengths λl must be inversely proportional to the square-roots of the number densities (λl2 nl = Cl) and may be taken as Debye lengths or skin-depths. A novel feature is that the `flow' current Σl ql nl vl in Ampere's law is augmented by a solenoidal `twirl' current Σl ∇ × ∇ × λl2 j flow,l. The resulting equations imply conserved linear and angular momenta and a positive definite swirl energy density E* which includes an enstrophic contribution Σl (1/2) λl2 l wl2. It is shown that the equations admit a Hamiltonian-Poisson bracket formulation. Furthermore, singularities in ∇ × B are conservatively regularized by adding (λB2/2 μ0) (∇ × B)2 to E*. Finally, it is proved that among regularizations that admit a Hamiltonian formulation and preserve the continuity equations along with the symmetries of the ideal model, the twirl term is unique and minimal in non-linearity and space derivatives of velocities.