论文信息 - Initiation of combustion and detonation by laser-induced electronical excitation of O2 molecules to the a1Δg and b1Σg+ states

Initiation of combustion and detonation by laser-induced electronical excitation of O2 molecules to the a1Δg and b1Σg+ states

On the basis of developed physical and mathematical model for thermal nonequilibrium chemical processes involving electronically excited molecules the analysis of the mechanisms resulting in initiation of combustion in closed reactor and detonation in supersonic flow behind inclined shock wave in H2+O2(air) mixtures at excitation of the (see paper for formula) states of oxygen molecules by resonant laser radiation with wavelengths (lambda) equals1.268 micrometers and 762 nm has been carried out. The numerical analysis has shown that induced by laser radiation excitation of O2 molecules leads to significant decrease of the autoignition temperature and allows to initiate detonation at very low temperature (~500 K) behind shock wave at relatively small values of laser radiation intensity. Excitation of (see paper for formula) state by laser radiation is more effective to influence on combustion kinetics and initiation of detonation in supersonic flow.

Alexander M. Starik | Nataliya S. Titova | A. Starik | N. Titova

[1] N. Brown,et al. Ignition by excimer laser photolysis of ozone , 1986 .

[2] M. Smooke,et al. Computational and experimental studies of laser-induced thermal ignition in premixed ethylene-oxidizer mixtures , 1995 .

[3] A. Starik,et al. On a possibility to reduce the ignition threshold for combustible mixtures by selective excitation of molecular vibrations in initial reagents , 2000 .

[4] Robert C. Brown. A theoretical study of vibrationally induced reactions in combustion processes , 1985 .

[5] A. Starik,et al. Low-temperature initiation of the detonation combustion of gas mixtures in a supersonic flow under excitation of the O2(a1Δg) state of molecular oxygen , 2001 .

[6] C. Amiot,et al. The magnetic dipole a1Δg → X3Σg− transition in the oxygen afterglow , 1981 .

[7] Jack A. Syage,et al. Dynamics of flame propagation using laser‐induced spark initiation: Ignition energy measurements , 1988 .

[8] Eugene P. Dougherty,et al. COMPUTATIONAL KINETICS AND SENSITIVITY ANALYSIS OF HYDROGEN-OXYGEN COMBUSTION , 1980 .

[9] A. Fridman,et al. The physics of a chemically active plasma , 1984 .

[10] A. Starik,et al. CHARACTERISTICS OF THE CHANGES IN THE REFRACTIVE INDEX DUE TO INTERACTION OF A RADIATION PULSE WITH AN INVERTED MEDIUM , 1994 .