On the product rotational state distribution in exoergic atom—diatomic molecule reactions

The distribution of product electronic states from the reactions hlz + X -hlX + hl\* for X1X = KCI, KBr, and RbBr is reexamined from the information theoretic viewpoint, using a hierarchy of prror distributions. Good agreement with experimental line intensities IS achieved using a surprisal linear i

Dcparrrrwnr uf Cixrmistr> . Statr\_ford Unil ersirj . Smnford. Calijornia 9J305. US.4 Kecrnsd 15 \_aprrl 1963: in find1 form 31 May 19S3 The effect of reagent rotation on the product vibrstional state distribution is reported for the reaction Ca('S) + W(S lx+." = 1.J) -Cal'(S"+, u'.J') + II( An infr

Even when a simple valence force field is used to represent the bound state normal modes, the kinetic energy operator couples bending and stretching motions in bent triatomic molecules. These bend-stretch couplings have been ignored in previous theoretical descriptions of photodissociation and are s

Simple "half-collision" classical trajectories on model potential surfaces show that the lack of leaving-atom isotope effects on initial rotational state distributions P(N) in reactions of the type M\*+H2 (HD) -+MH( v, N) +H (D) would result from decomposition of H-M-H( D) intermediates on anisotrop

The reaction C( 'P) +NsO(% \*C+) is studied by varying the kinetic energy of C(3P) in two center-of-mass regimes: 0.1-0.2 eV and 2-7 eV. C( 3P) is directly observed, and the C, velocity distribution is estimated from the time-of-flight of Cs. CN(X %+) is vibrationally inverted and rotationally 'hot'