Photodissociation of the NO dimer: rotational energy distribution and alignment of the NO(B 2Π) fragments

The rotational alignment As) of the NO(A) fragments in the photodissociation of the NO dimer at 193 nm has been determined based on the polarization response of the laser-induced fluorescence in the E %+-A 'Z+ transition. The observed alignment Ah\*) is negative, with increasing magnitude in higher

An experiment to measure the product internal state distribution in the infrared predissociation of (NO)\* (Y,,) has been performed, using (2 + 2) REMPI as the detection technique. The results show that a small amount of the excess energy is converted into rotation. Comparison with earlier data conc

The vibrational and rotational stotc distributions as well as the uansbtional energy have been measured fcr the nascent NO fra=nent afrcr photodissociation of dimcthylniuosamine at 363.5 nm. Four differat vibrational smtes (u" = O-3) and rornrion~l transitions with qunnrum numbzrs up IOJ' = 50 were

Alignment effects in the highly rotating NO X %I vn = 1 fragment generated from photodissociation of CHaONO mr\* at 355 nm have been probed by two-photon laser-induced fluorescence spectra. From polarization experiments the rotational angular momentum of NO fragments was shown to be aligned preferen

Photodissociation of jet-cooled NOCl at 355 and 499.4 nm proceeds via parallel and perpendicular transitions, respectively, and the dissociation is fast and direct. State-specific NO spin-orbit and A-doublet population ratios are observed. At 355 nm, [ NO( \*II& ] a [N0(2111,2) 1, and the Adoublet c

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