Abstract:
On the basis of the generalized Enskog kinetic equation, the problem of the structure of a shock wave in dense reacting gases and liquids is solved. It is shown that the physicochemical processes in the zone of translational nonequilibrium (ZTN) in the shock wave front do not obey the Arrhenius kinetics. The rates of high-threshold processes in the ZTN in the shock wave front may exceed these rates in equilibrium behind the front by a factor of $10^6$ and more. An analytical expression is obtained for the rate constant of nonequilibrium processes in the front. Comparison of the results of calculation of the yield of products with broken double bond in the benzene molecule with the experimental data reveals that the formation of these products proceeds by the mechanism of nonadiabatic collisions realized under highly nonequilibrium conditions.
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