Abstract
A model of a stationary glow-type discharge in atmospheric-pressure air operated in high-gas-temperature regimes (1000 K < Tg < 6000 K), with a focus on the role of associative ionization reactions involving N(2D,2P)-excited atoms, is developed. Thermal dissociation of vibrationally excited nitrogen molecules, as well as electronic excitation from all the vibrational levels of the nitrogen molecules, is also accounted for. The calculations show that the near-threshold associative ionization reaction, N(2D) + O(3P) → NO+ + e, is the major ionization mechanism in air at 2500 K < Tg < 4500 K while the ionization of NO molecules by electron impact is the dominant mechanism at lower gas temperatures and the high-threshold associative ionization reaction involving ground-state atoms dominates at higher temperatures. The exoergic associative ionization reaction, N(2P) + O(3P) → NO+ + e, also speeds up the ionization at the highest temperature values. The vibrational excitation of the gas significantly accelerates the production of N2(A3∑u+) molecules, which in turn increases the densities of excited N(2D,2P) atoms. Because the electron energy required for the excitation of the N2(A3∑u+) state from N2(X1∑g+, v) molecules (e.g., 6.2 eV for v = 0) is considerably lower than the ionization energy (9.27 eV) of the NO molecules, the reduced electric field begins to noticeably fall at Tg > 2500 K. The calculated plasma parameters agree with the available experimental data.
Highlights
Several kinetic schemes have been proposed in the literature for modelling atmospheric pressure nonequilibrium air discharges, such as streamers [1,2], low-current arc and glow discharges at rest [3,4,5,6], glow discharges in fast gas flows [7,8,9], and high-current pulsed discharges [10,11,12,13,14,15]
It is found that the ionization by electron impact of O2 and N2 molecules dominates at low-gas temperature (Tg is below the range of 1000–2000 K [10,14,15]), while the electron-impact ionization of NO molecules is written as: e + NO → NO+ + e, (R3)
Low-current discharges in atmospheric-pressure air have been studied in a number of experiments
Summary
Several kinetic schemes have been proposed in the literature for modelling atmospheric pressure nonequilibrium air discharges, such as streamers [1,2], low-current arc and glow discharges at rest (or in low gas flows) [3,4,5,6], glow discharges in fast gas flows [7,8,9], and high-current pulsed discharges [10,11,12,13,14,15]. Plasma 2020, 3 where R refers to the reactions used in the model This electron-impact ionization is favored by its low ionization energy of 9.27 eV and dominates at high gas temperatures [3,4,14,15]. The major difference between the kinetic schemes proposed in the literature for modelling atmospheric-pressure air glow discharges [3,4,5,6,7,8,9] and the one used in this work is that the present model takes into account ionization processes involving excited-state atomic collisions. It should be noted that the proposed reaction kinetic scheme did not include three-body reactions for the generation of N4 + and O4 + These cluster ions play only a dominant role in atmospheric-pressure air discharges at low gas temperature (Tg < 900 K). The translational thermal conductivity of heavy particles was taken from [31]
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