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Thermodynamically Consistent Vibrational-Electron Heating: Generalized Model for Multi-Quantum Transitions

Plasma Physics 2026-03-13 v3

Abstract

Accurate prediction of electron temperature (TeT_{\rm e}) is critical for non-equilibrium plasma applications ranging from hypersonic flight to plasma-assisted combustion. We recently proposed a thermodynamically consistent model for vibrational-electron heating [Phys. Fluids 37, 096141 (2025)] that enforces the convergence of TeT_{\rm e} to the vibrational temperature (TvT_{\rm v}) at equilibrium. However, the original derivation was restricted to single-quantum transitions, limiting its validity to low-temperature regimes (Te1.5T_{\rm e} \lesssim 1.5 eV). In this Letter, we generalize the model to include multi-quantum overtone transitions, extending its applicability to high-energy regimes. We demonstrate that previous models neglecting hot-band transitions incur a systematic heating error of exp(θv/Tv)\exp(-\theta_{\rm v}/T_{\rm v}), where θv\theta_{\rm v} is the characteristic vibrational temperature. This error exceeds 40% when TvT_{\rm v} is greater than θv\theta_{\rm v}, effectively preventing thermal relaxation. To correct this, we derive a formulation where the total heating rate is a summation of channel-specific cooling rates Qev(m)Q_{\rm e-v}^{(m)}, each associated with a quantum jump mm, scaled by a thermodynamic factor exp(mθv/Temθv/Tv)\exp(m\theta_{\rm v}/T_{\rm e}-m\theta_{\rm v}/T_{\rm v}). This generalized model preserves thermodynamic consistency by ensuring zero net energy transfer at equilibrium.

Keywords

Cite

@article{arxiv.2512.23072,
  title  = {Thermodynamically Consistent Vibrational-Electron Heating: Generalized Model for Multi-Quantum Transitions},
  author = {Bernard Parent and Felipe Martin Rodriguez Fuentes},
  journal= {arXiv preprint arXiv:2512.23072},
  year   = {2026}
}

Comments

4 pages, 1 figure

R2 v1 2026-07-01T08:43:39.370Z