Gyrokinetic Theory of Linear Gravitational Flute Interchanges with Flow Shear Stabilization

A collisionless electrostatic gyrokinetic theory is developed to describe how the presence of a differential velocity shear can help stabilize linear gravitational flute interchanges in slab geometry.

This is made possible because the velocity shear acts to increase the perpendicular wavenumber of the unstable modes with time.

Eventually, a threshold wavenumber is crossed where the effect of gyroaveraging, captured by the \(J_0\) Bessel function in the gyrokinetic equation, results in a damping of the instability by nature of \(J_0\) being a decaying sinusoidal.

However, transient amplification, responsible for subcritical turbulence, can still occur.

Numerical comparisons are made with a Magnetohydrodynamic model with gyroviscous corrections as well as the GX gyrokinetic code.

It is demonstrated that an increasing shear acts not only to accelerate the stabilization effect but also to reduce the overall transient amplification.