Kinetics of excited species at high specific energy deposition: Quenching by electrons in the afterglow of a nanosecond capillary discharge

Depopulation of electronically excited nitrogen state, N₂(C³П_u,v’ = 0), in the afterglow of capillary nanosecond pulsed discharge in pure nitrogen is studied. It is found experimentally that an additional collisional mechanism appears and dominates at high specific deposited energies leading to the anomalously fast deactivation of the N₂(C³П_u). On the basis of obtained experimental data and of the analysis of possible quenching agents, it is concluded that the anomalously fast deactivation of the N₂(C³П_u) can be explained by the quenching by electrons. Long-lived plasma at time scale of hundreds nanoseconds after the end of the pulse is observed. High electron densities, about 10¹⁴cm^–3at 27 mbar, are sustained by a reaction of associative ionization. Kinetic 1. D numerical modeling and comparison of calculated results with experimentally measured electric fields in the discharge and electron density measurements in the afterglow confirm the validity of the suggested mechanism.