Shock Tube Study of the Reaction of H Atoms with SnCl4.

The reaction of H atoms with SiCl 4 was studied behind reflected shock waves at temperatures between 1530 K and 1730 K and pressures around 1.5 bar by applying atomic resonance absorption spectroscopy (ARAS) for time resolved measurements of H atoms at the L ␣ -line. The thermal decomposition of a f

## Abstract The reactions of dimethyl ether (CH~3~OCH~3~, DME) with O(^3^P) and H atoms have been studied at high temperatures by using a shock tube apparatus coupled with atomic resonance absorption spectroscopy (ARAS). The rate coefficients for the reactions CH~3~OCH~3~ + O(^3^P) → CH~3~OCH~2~ +

Atomic resonance absorption spectroscopy (ARAS) was applied to measure S atoms, behind shock waves in COS/Hz pyrolysis or CSz/Hz photolysis systems. Both the pyrolysis of COS and the photolysis CSz was used to generate the S atoms, which subsequently reacts with H2 via the reaction: The photolysis

Reactions of the hydroxyl radical with several linear hydrocarbon species occurring in combustion chemistry have been considered at temperatures near I100 K and 1 atmosphere in shock tube experiments The OH density was monitored using 310 nm UV absorption of the A 'E+ -X 'n transition Rate coefficie

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

NO 2 concentration profiles in shock-heated NO 2 /Ar mixtures were measured in the temperature range of 1350 -2100 K and pressures up to 380 atm using Ar ϩ laser absorption at 472.7 nm, IR emission at , and visible emission at 300 -600 nm. In the course of this study, the absorption coefficient of N