The determination of the O2-O collision cross section from shock-tube emission studies

The rate coefficient for the reaction (1) OH + OH --\* HzO + 0 has been determined in mixtures of nitric acid (HNO3) and argon in incident shock wave experiments. Quantitative OH time-histories were obtained by cw narrow-linewidth uv laser absorption of the Rl(5) line of the A2 x+ + X 2 ni (0,O) tra

N2O decay has been monitored via infrared emission for a series of mixtures containing N20/Ar and N20/H2/Ar. These mixtures were studied behind reflected shock waves in the temperature interval of 1950-3075' K with total concentrations ranging from 1.2 to 2.5 X 1OI8 molec/cm3. In all cases the N2O d

The ~mnslufionrtl energy distribution of H\*(n = 4) arising from e-H10 collisions has been measured. The absolute cross action for thr process leading to !he slowest component has been estimated in the energ range 25-300 eV and is cotnparcd \vith thcorcticlil predictions. ## An optical emission

The formation and consumption of CH radicals during shock-induced pyrolysis of a few ppm ethane diluted in argon was measured by a ring-dye laser spectrometer Absorption-overtime profiles, measured at a resonance line in the Q-branch of the A2A -X211 band of C H at A = 431.1311 nm. were recorded and

## Abstract The reaction of CH~2~O with NO~2~ has been studied with a shock tube equipped with two stabilized ew CO lasers. The production of CO, NO, and H~2~O has been monitored with the CO lasers in the temperature range of 1140–1650 K using three different Ar‐diluted CH~2~O‐NO~2~ mixtures. Kinet