The deactivation of N2B3Πg, ν = 0–2 and N2a′1Σ−u, ν = 0 by nitrogen

Branching fractions are determined for the product NO (A 'X+, u= 0,l) and NO( B 'II, v= 0) emissions as a function of v' in the energy transfer reaction N,(A 'Z:, v') tNO(X 211n v"=O) in a rapidly pumped discharge-flow reactor operated at a total 2 pressure of TC 2 Torr at % 295 K. Using the NO( A Z

The collision-induced intramolecular energy transfer N2 (A '2: ) + M+N2 (B 'll,) + M was studied under molecular beam conditions using Xe and Nz as the collision partners. Specifically, the near-resonant transfer between the levels A, VI'= 1 O-B, u'= 2 was investigated by means of the product emissi

Time-resolved fluorescence hscr-induced spectroscopy was used to determine the quencbin~ rates of the vibrations1 Icvets u' = 0,l and 2 of NG(B \*f+ \_,,) bv I& and Ne. For bolt2 quenchers rate constants mz found to base a depcndenoz upon \_ the vibrational escitation of the Ievef. Tlie radiative Ii

Branching fractions are determined for the product NO(A2X +, v = 0, 1 and 2) and NO(B 2I-Ir, v = 0) emissions as a function of v' in the title reaction. Using the NO(A2X +, v' = 0-2 ~ X 2lit, v") "r, Av = v' -v" = -4, -5 and -6 and the NO(B2FIr, v'=0~X2Ilr, v") /3, Av=-6 and -7 band intensities we d

Collisional deactivation rate constants of CO+ A 'fI(v=O and 2) by He, Ne. Ar, N,, and CO have been determined by using a time-resolved laser-induced fluorescence technique. The results were combined with the previously determined Y= 1 rate constants to obtain an interesting u dependence of the rate

Tie-resolved fluorescence laser-induced spectroscopy was used to examine the quenching of the vibrational levels v = 0 and u = 1 of N;(B \*C:) by N2\_ The rate coefficients of the quenching reactions are found to be constant over the tempera ture range 300-500 K. The quenching constant for the u = 1