Influence of translational and internal energy upon the chemiluminiscent part of the exothermic reaction NO + O3 → NO*2 + O2 → NO2 + hν + O2

Ihe reactions of CC1302 with NO and NO2 have been studied by steady-state photolqsis of Clz-HCCl,-Oz-&-NO --NOz mixtures at =I atm: CCl30, + NO -Ccl,0 + NO, (3), CCt,O, + NO2 (t hl) \* CCl,02NOt (+ hi) (4. A); k&k3 = 0.68, independent of temperature-The thermal decomposition of CC1302N02 via the bac

The air-afterglow reaction NO + 0 + NO1 + hv comprises a two-body radiative recombinntion at s rnte of 4.2 X lo-18 cm3 molecule-' set-1 and a three-body process at a rate of 7 X 1O-32 cm6 molecule-\* xc-l with 02 3s third body. Within experimental error limits, the yield of the chemiluminescent thre

Pulse radiolysis was used to study the kinetics of the reactions of CH 3 C(O)CH 2 O 2 radicals with NO and NO 2 at By monitoring the rate of formation and decay of NO 2 295 K. using its absorption at the rate constants 400 and 450 nm k(CH C(O)CH O ϩ NO) ϭ (8 Ϯ 3 2 2 and were de-Ϫ12 Ϫ12 3 Ϫ1 Ϫ1 2) ϫ

## Abstract The atmospheric reaction NO~2~ + O~3~ → NO~3~ + O~2~ (1) has been investigated theoretically by using the MP2, G2, G2Q, QCISD, QCISD(T), CCSD(T), CASSCF, and CASPT2 methods with various basis sets. The results show that the reaction pathway can be divided in two different parts at the M