Further IR spectroscopic evidence for the formation of CH2(OH)OOH in the gas-phase reaction of HO2 with CH2O

Fourier transform infrared spectroscopy was used to identify CH2FOOH and HC(O)F as products of the gas-phase reaction of CHIFOz radicals with HOs radicals. At 700 Torr and 295 + 2 K, branching ratios for the CHrFOOH forming channel, k,,/k, =0.29 f 0.08 and the HC(O)F channel, klb/kl =0.71 f 0.11 wer

Rate constants for the reactions of OH radicals and Cl atoms with CH,CH,NO>, CH,CH,CH,NO,, CH3CH2CH2CHzN02, and CH,CH2CH2CH,CH2N02 have been determined at 295+3 K and a total pressure of approximately 1 atm. The OH rate data were obtained using both the absolute rate technique of pulse radiolysis co

## Abstract The gas phase reaction kinetics of OH with three di‐amine rocket fuels—N~2~H~4~, CH~3~NHNH~2~, and (CH~3~)~2~NNH~2~—was studied in a discharge flow tube apparatus and a pulsed photolysis reactor under pseudo‐first‐order conditions in [OH]. Direct laser‐induced fluorescence monitoring of

## Receiwd 16 Ma> 1979 MoIecuhr modulation spectrometry has been employed to mesure the rate constants for the reactions ofCHxO2 with HOz. NO2 and X0. A negnthe tcmpcraturc dependence is reported for the rextion nirh HO\_r. Product spectra are giwn for the reactions with lIOt and NO?\_

Plash photolysis kinetic absorption spectroscopy was used to investigate the gas phase reaction between hydroperoxy (HO,) and methylperoxy (CH302) radicals at 298 K. Due to the large difference between the self-reactivities of the two radicals, firstor second-order kinetic conditions could not be ma