Branching fractions of the product NO(A 2Σ+, ν = 0, 1 and 2) and NO(B 2Πr, ν = 0) emissions observed as a function of ν′ in the energy transfer reaction CO(a 3Π, ν′) + NO(X 2Πr, ν″ = 0)

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 formation of NO (A,v) and NO(B,v) was investigated from the reaction Co(a,v') + NO(X,v" -0) in a beam-beam configuration. The nascent rovibrational distributions of NO(A,v-0-2) and NO(B,v-0-2) were determined from NO(A ~ X) and NO(B ~ X) emissions by means of spectral simulation. The branching r

N2B3ng, Y = O-2 and N\*a"v;, Y = 0 were produced by pulsed rodiolysis af nitrogen (100-2000 torr) and fo!lowed by fast kinetic absorption spectroscopy in the second and fifth positive system. T!le rate constants for the denctivation of the species by nitrogen were found to be ~N~A,~ = 1.6i + 0.8; 2.

The dipole moment of NO(B 2I-1) was determined for the first time by high resolution laser-induced fluorescence molecular beam spectroscopy. Specific values obtained are as follows: /x(v' = 3) = 0.2933 D, /x(v' = 4) = 0.2769 D and /x(v' = 5)= 0.2617 D. An RKR analysis allowed the first two moments o

The energy transfer reaction of metastable N2(a lI-Ig, v') prepared by a dc discharge of high-purity nitrogen with CO(X 1E, v" = 0) was investigated by measuring the vacuum ultraviolet emission spectra of the electronically excited species CO(A 11-1, v') and NE(a lIIg, v') during the collision perio

The rotational structure of the 2B, state of NO\* is analyzed by means of the time-gated escitation spectrum. monitored at the 3v2 band. The band origins ~0 and the rotational constants are evaluated from the observed data: vo = 20204.86 cm-t.