Electronic quenching and vibrational relaxation of no A2Σ(υ′=1 and υ′=0) by collisions with H2O

Rate coefficients for the total destruction, ktot =X-r + kq (kq is the rate coefficient for quenching collisions) and for rextiue colliiions, Xr,, have been obtained for the interactions of NZO;, u > 0) in the energ>' regime from thermal to OA and 1.5 cV. Ec\_m\_. respectively using a selected ion f

The quenching re.ac!ions 01 memsmble niwogcn molecuks I$(A%. u = 0. I. 2) by 02 has been sludisd in a rrmperamrscontrolled flowing afterglow experimenl. The rexlion tale constants at 300 K are 2.5 X IO-"\_ 4.0X IO-" and 4.5 X lo-" c&/s molecule for u = 0. 1 and 2, respectively. They vary as Z"' m th

NO was irmdiated by a iow-pressure iodine discharge lamp which induced fluorescence from excited NO molecules. From analysis of fluorescence spectm it was found that the A %?(u = 5). C2H(u' = 1) and B 2H(u' = 8) states were excited by iodine atomic lines at 179.9,183.0 and 187.6 nm. respectively. By

Nz(A. u = O-3) produced by the AI(~P~,~) + N2 reaction and detected by laser-induced fluorescence undergoes rapid, stcpwise vibrational relaxation but slow electronic quenching with added CH4 or CF4. Rate constants, k& of 1.5,3.1, and 5.0 X lo-l2 cm3 s-' are measured for Q = CH4, u = 1-3, and O-47,1

Fully converged quantum cross sections for 4He-D2 (u= l,i=O) vibrational reliaxation were determined using the coupled-states method and a modikied version of the Gordon-Secrcst surface. First-order forbidden rotational transitions play a si@fkant role, comparable to that observed previously for the

The collisional quenching of OH A'Z(u' = 1) by Hz0 was determined from laser-induced fluorescence measurements in the burned-gas region of stoichiometric H,/OJAr flames at low pressure ( 19 and 38 Torr). The collisional quenching was measured as a function of the initial laser-populated rotational l