On the reaction of the NH2 radical with ozone

The decay kinetics of NH2 radicals formed by flad~ photolysis of NH3 f-02 and NH3 + N, mixtures at total pressures below 30 Torr were studied using the inrra-caviry laser spectroscopy technique. An upper limit of 3 X IO-l8 cm3 molecule-' s-' wx measured for the reaction of NH2 with oxygen. The data

The reaction of the NH, radical with NO, NH2 +NO+k, products, was investigated using intracavity laser spectroscopy. The temperature dependence of k, [T) over the range 295-620 K is well approximated by the expression k, ( T) = (2,0? 0.4) X 1 O-'I x (T/298)-"' cm3 s-l. The branching ratios for the

## Abstract The absolute rate constant for the reaction of methyl radicals with ozone has been measured as a function of temperature. Small concentrations of CH~3~ were generated by flash photolyzing CH~3~NO~2~ at 193 nm with an ArF laser. A photoionization mass spectrometer was used to follow the

The kinetics of the reaction NH2 + NO + N2 f Hz0 were studied, I;sins a conventional flash photolysis system. PI VdUC of k, = (1.1 s 0.2) x 10'0 E mole-' s-1 was obtained at room tempcralure and in the pressure ran\_-2-700 ton in the presence of nitrogen. A slight negative tcmpcrature cocfiicient wa

The absolute rate constant of the reaction between NH2 and ozone has been measured using a flash photo&is--laser resonance techmque and found to be 4 = 6.3 (~1.0) X IO-l4 cm3 molecule-' S-I at room temperature. The &hen&s expressIon, determined from measurements in the temperature range 298-380 K IS

The geometries of the reactant, products, and transition state of the title reaction were optimized at the UHF and UMP2 levels with the double and triple zeta basis sets as well as polarization functions by using the energy-gradient method. The potential-energy barrier for this reaction is 3.73 kcal