Vibrational relaxation and triggering of the non-equilibrium vibrational decomposition of CO2 in gas discharges

Abstract

Non-equilibrium vibrational dissociation of CO2 at low translational-rotational temperatures T is investigated computationally for conditions of microwave induced plasmas. Semi-analytic treatment of vibrational relaxation in CO2 in shock tube and acoustic experiments is summarized. A state-to-state vibrational kinetics model applied for the simulations is benchmarked and adjusted to the relaxation times obtained in gas dynamic experiments. The governing parameter Q/n20 has been introduced, where Q is the specific volumetric power coupled in plasma and n0 is the initial number density of CO2. The modelling results indicate a rapid increase of the rate of the primary dissociation process CO2 + M CO + O + M when Q/n20 exceeds some critical value. A simple analytic calculation of ( Q/n20 )crit is proposed which agrees well with the numerical results. At T=300 K the estimated ( Q/n20 )crit 6·10-40~W·m3.