Reduced magnetohydrodynamic theory of oblique plasmoid instabilities

Abstract

The three-dimensional nature of plasmoid instabilities is studied using the reduced magnetohydrodynamic equations. For a Harris equilibrium with guide field, represented by Bo = Bpo (x/λ) y + Bzo z, a spectrum of modes are unstable at multiple resonant surfaces in the current sheet, rather than just the null surface of the polodial field Byo (x) = Bpo (x/λ), which is the only resonant surface in 2D or in the absence of a guide field. Here Bpo is the asymptotic value of the equilibrium poloidal field, Bzo is the constant equilibrium guide field, and λ is the current sheet width. Plasmoids on each resonant surface have a unique angle of obliquity θ (kz/ky). The resonant surface location for angle θ is xs = - λ ( θ Bzo/Bpo), and the existence of a resonant surface requires |θ| < (Bpo / Bzo). The most unstable angle is oblique, i.e. θ ≠ 0 and xs ≠ 0, in the constant- regime, but parallel, i.e. θ = 0 and xs = 0, in the nonconstant- regime. For a fixed angle of obliquity, the most unstable wavenumber lies at the intersection of the constant- and nonconstant- regimes. The growth rate of this mode is γmax/o SL1/4 (1-μ4)1/2, in which o = VA/L, VA is the Alfv\'en speed, L is the current sheet length, and SL is the Lundquist number. The number of plasmoids scales as N SL3/8 (1-μ2)-1/4 (1 + μ2)3/4.