arXiv:2511.21944v1 Announce Type: new
Abstract: Accurate prediction of electron temperature ($T_{rm e}$) in non-equilibrium plasma flows is critical for applications ranging from hypersonic flight to plasma-assisted combustion. We recently proposed a thermodynamically consistent model for vibrational-electron (V-e) heating [Phys. Fluids 37, 096141 (2025)] which enforces convergence of $T_{rm e}$ to the vibrational temperature ($T_{rm v}$) at equilibrium. While the original derivation assumed electron energy loss was dominated by collisions with ground-state molecules, this Letter presents a rigorous generalization of the model. We demonstrate that the heating-to-cooling ratio $exp(theta_{rm v}/T_{rm e}-theta_{rm v}/T_{rm v})$ with $theta_{rm v}$ the characteristic vibrational temperature remains valid even when electron cooling interactions with vibrationally excited states are included. This derivation removes the previous constraint assuming ground-state dominance, thereby extending the model’s validity to plasma flows where vibrationally excited populations contribute significantly to electron cooling.