Vibrational nonequilibrium and reaction heat effect in diluted hydrogen-oxygen mixtures behind reflected shock waves at 1000 <T < 1300 K

Vibrational nonequilibrium and reaction heat effect in diluted hydrogen-oxygen mixtures behind reflected shock waves at 1000 <T < 1300 K

Vibrationally nonequilibrium model of kinetics in the reacting mixture H2 + O2 + Ar behind the reflected shock wave is formulated as a non-isothermal process occurring adiabatically at a constant volume. The model takes into account the vibrational nonequilibrium for the starting (primary) H2 and O2...

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Veröffentlicht in:International journal of hydrogen energy 2020-01, Vol.45 (4), p.3251-3262
Hauptverfasser: Skrebkov, O.V., Kostenko, S.S., Smirnov, A.L.
Format: Artikel
Sprache:eng
Schlagworte:
Chemical kinetics
Chemistry
Chemistry, Physical
Electrochemistry
Electronical excitation
Energy & Fuels
Heat effect
Physical Sciences
Science & Technology
Shock wave
Technology
Vibrational relaxation
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Zusammenfassung:Vibrationally nonequilibrium model of kinetics in the reacting mixture H2 + O2 + Ar behind the reflected shock wave is formulated as a non-isothermal process occurring adiabatically at a constant volume. The model takes into account the vibrational nonequilibrium for the starting (primary) H2 and O2 molecules, as well as the molecular intermediates HO2, OH, O2(1Δ), and the main reaction product H2O. Calculation results that simulate experimental data on the ignition induction time measurements in the hydrogen oxygen mixtures behind reflected shock waves by the methods of absorption spectroscopy (monitoring the OH(2Π) radical) and emission spectroscopy (monitoring the OH*(2Σ+) radical) at temperatures of 1000 
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2019.11.168