Kinetic and Continuum Modeling of High-Temperature Air Relaxation

Kinetic and Continuum Modeling of High-Temperature Air Relaxation. Gimelshein, S. F., Wysong, I. J., Fangman, A. J., Andrienko, D. A., Kunova, O. V., Kustova, E. V., Morgado, F., Garbacz, C., Fossati, M., & Hanquist, K. M. Journal of Thermophysics and Heat Transfer, 2022.
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Fully kinetic, vibrationally kinetic, and continuum solvers with varying model fidelity are used in this work to model the high-temperature relaxation of air in 7230 and 15,000 K adiabatic heat bat...

@article{gimelshein2022,
	title = {Kinetic and {Continuum} {Modeling} of {High}-{Temperature} {Air} {Relaxation}},
	doi = {10.2514/1.T6462},
	abstract = {Fully kinetic, vibrationally kinetic, and continuum solvers with varying model fidelity are used in this work to model the high-temperature relaxation of air in 7230 and 15,000 K adiabatic heat bat...},
	journal = {Journal of Thermophysics and Heat Transfer},
	author = {Gimelshein, Sergey F. and Wysong, Ingrid J. and Fangman, Alexander J. and Andrienko, Daniil A. and Kunova, Olga V. and Kustova, Elena V. and Morgado, Fabio and Garbacz, Catarina and Fossati, Marco and Hanquist, Kyle M.},
	year = {2022},
	keywords = {CFD, Chemical Equilibrium, Direct Simulation Monte Carlo, Heat Flux, High Enthalpy Shock Tunnel, Hypersonic Flows, Nonequilibrium Thermochemistry, Nonequilibrium Vibrational Chemical Kinetics, Stagnation Point, Vibrational Energy, own},
	pages = {1--23},
}

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