One-dimensional detonation waves are simulated with the three-step chain branching reaction model, and the instability criterion is studied. The ratio of the induction zone length and the reaction zone length may be used to decide the instability, and the detonation becomes unstable with the high ratio. However, the ratio is not invariable with different heat release values. The critical ratio, corresponding to the transition from the stable detonation to the unstable detonation, has a negative correlation with the heat release. An empirical relation of the Chapman-Jouguet Mach number and the length ratio is proposed as the instability criterion
Using the combined limits of a large activation energy and a ratio of specific heats close to unity,...
In this study, the surface instability of oblique detonation waves (ODW) formed by two-dimensional, ...
This presentation reports on numerical results for the evolution of a detonation wave that is expand...
One-dimensional detonation waves are simulated with the three-step chain branching reaction model, a...
The nonlinear dynamics of one-dimensional pulsating detonations were studied numerically using a sim...
The hydrodynamic mechanisms behind the instability and failure of a one-dimensional pulsating detona...
e sa s be fifth unstable detonation waves. The study shows that the rate of convergence depends on t...
The stability properties and dynamic behavior of steady and quasi-steady detonation theories are inv...
The chemical-gas dynamic mechanisms behind the instability and failure of a one-dimensional pulsatin...
The structure of the steady planar detonation wave is analyzed for three-step chain-branching kineti...
The linear receptivity and stability of plane idealized detonation with one-step Arrhenius type reac...
WOS:000332844200022International audienceThis investigation deals with the study of the mean structu...
WOS:000360952400005International audienceThis paper deals with some salient features of numerical de...
The propagation of non-ideal detonations arising from friction, heat transfer and reactions steps in...
The role of chain-branching cross-over temperatures in shock-induced ignition of reactive materials...
Using the combined limits of a large activation energy and a ratio of specific heats close to unity,...
In this study, the surface instability of oblique detonation waves (ODW) formed by two-dimensional, ...
This presentation reports on numerical results for the evolution of a detonation wave that is expand...
One-dimensional detonation waves are simulated with the three-step chain branching reaction model, a...
The nonlinear dynamics of one-dimensional pulsating detonations were studied numerically using a sim...
The hydrodynamic mechanisms behind the instability and failure of a one-dimensional pulsating detona...
e sa s be fifth unstable detonation waves. The study shows that the rate of convergence depends on t...
The stability properties and dynamic behavior of steady and quasi-steady detonation theories are inv...
The chemical-gas dynamic mechanisms behind the instability and failure of a one-dimensional pulsatin...
The structure of the steady planar detonation wave is analyzed for three-step chain-branching kineti...
The linear receptivity and stability of plane idealized detonation with one-step Arrhenius type reac...
WOS:000332844200022International audienceThis investigation deals with the study of the mean structu...
WOS:000360952400005International audienceThis paper deals with some salient features of numerical de...
The propagation of non-ideal detonations arising from friction, heat transfer and reactions steps in...
The role of chain-branching cross-over temperatures in shock-induced ignition of reactive materials...
Using the combined limits of a large activation energy and a ratio of specific heats close to unity,...
In this study, the surface instability of oblique detonation waves (ODW) formed by two-dimensional, ...
This presentation reports on numerical results for the evolution of a detonation wave that is expand...
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