Energy Calculation of Magnetohydrodynamic Waves and Their Stability For Viscous Shearing Flows

A self-consistent, thermodynamic approach is employed to derive the wave energy of a magnetohydrodynamic system within the harmonic approximation and to obtain the familiar dispersion relation from the resulting equation of motion. The evolution of the system due to an external perturbation is studied by a linear response formalism, that also gives the energy absorbed by the magnetohydrodynamic system from the external field. The calculated wave energy reveals the presence of positive and negative energy waves, that coalesce together to give rise to Kelvin - Helmholtz instability of the system. The threshold value of this instability changes only slightly in the presence of a small amount of viscosity, thus precluding the dissipative instability of the negative energy waves. The prediction of such a dissipative instability by earlier authors turns out to be the result of an erroneous choice of the viscous drag force, that violates the fundamental law of Galilean invariance.