Photochemical determination of the high pressure limiting rate constant of the reaction H + NO + M = HNO + M

Potential-energy surfaces for various channels of the reaction have HNO ϩ NO 2 been studied at the G2M(RCC,MP2) level. The calculations show that direct hydrogen abstraction leading to the products should be the most significant reaction mech-NO ϩ cis-HONO anism. Based on TST calculations of the rat

Relative rate measurements of the reactions of the HO-radical with CO [HO + CO -+ H + COa (1) ] and with isobutane [HO f iso-C4H10 -t Hz0 f f-(or iso-)CaHg ( 3)J have been made through the photolysis of dilute mixtures of HONO with CO, ixo-Cd H ro, N0a, and NO in simulated air at 700 and 100 torr pr

The rate of the reaction (1) NO + HOz + OH + NO2 was determined in an isothermal discharge flow reactor with a combined ESR-LMR detection under pseudo-first-order conditions in HOz. The rate constant was identical in experiments with two different HOn sources: F + H202 and H + 0 2 + M. The absolute

## Abstract A rate constant for the reaction of NO~3~ with propene has been determined by an absolute rate technique at room temperature and atmospheric pressure. Experiments were performed in a Pyrex photoreactor coupled to two multiple reflection optical systems interfaced to a FTIR spectrometer

An upper limit for the reaction rate of CO with the nitrate radical NO, has been determined equal to 4 x lo-'' cmt3 molec-' s-' a t 295 ? 2 K. In the experiment the isotopic species C13016 and C13018 mixed at 1-2 ppmv level in synthetic air have been reacted with NO3 and the reaction followed using