Non-equilibrium ionisation of molecular hydrogen in electrical discharges

Abstract

Ionisation rates of molecular hydrogen in electrical discharges have been calculated by solving a system of vibrational master equations coupled to the Boltzmann equation for the electron energy distribution function. The influence of vibrational excited molecules on the ionisation rate can overcome up to a factor of 10 the corresponding contribution coming from the ground vibrational level of H₂(X¹ Sigma _g) due to the fact that electron-vibration and vibration-vibration energy exchanges populate the vibrational levels of H₂ and that the ionisation cross-sections of the process e+H₂(X¹ Sigma _g, nu ) to e+H₂⁺(² Sigma _g)+e present threshold energies decreasing with increasing vibrational level nu . A complete set of ionisation cross-sections (for all vibrational levels) has been calculated by using Gryzinski's theory and the Franck-Condon principle.