Gyrokinetic theory of slab universal modes and the non-existence of the Gradient Drift Coupling (GDC) instability

Abstract

A gyrokinetic linear stability analysis of a collisionless slab geometry in the local approximation is presented. We focus on k=0 universal (or entropy) modes driven by plasma gradients at small and large plasma β. These are small scale non-MHD instabilities with growth rates that typically peak near k_i 1 and vanish in the long wavelength k 0 limit. This work also discusses a mode known as the Gradient Drift Coupling (GDC) instability previously reported in the gyrokinetic literature, which has a finite growth rate γ= β/[2(1+β)] Cs/|Lp| with Cs2=p0/0 for k 0 and is universally unstable for 1/Lp≠ 0. We show the GDC instability is a spurious, unphysical artifact that erroneously arises due to the failure to respect the total equilibrium pressure balance p0+B02/(8π)=constant, which renders the assumption B0'=0 inconsistent if p0'≠ 0.