Electron kinetics in standing and moving striations in argon gas

The electron kinetics in moving and standing striations in direct current and radio frequency discharges is studied. The discharge current is such that the thermalizing electron–electron collisions are negligible, and the hydrodynamic description of the electron component of plasma is not valid. Therefore, the one-dimensional hybrid model is used, which models the electron component by the particle method, while the ions are described using the drift–diffusion approximation. It is obtained that the electron transport is nonlocal in space. The electron energy distribution in both discharges is of nonequilibrium nature, which is responsible for the nonlinearity of the ionization frequency. However, their dynamics in both discharges differs significantly. Namely, in the direct current discharge, the distribution function is strongly modulated by the striation passage, while in the radio frequency discharge, the electron energy relaxation time is such that the electron distribution function does not react on the oscillating electric field but is defined by the effective electric field.