Quantum-mechanical differential reaction cross sections for the F + H2(ν = 0) - FH(ν′= 2.3) + H reaction

## Appro\unate d~flizrcntwl cross sccl~ons are c&xl&d (using collmcar exact quantum reaction S matrices with tnnslttun SISIU theory) for the r+H2(u = 0) -H~(u' = 2), H~(u' = 3) + H rcact~ons at translational cnergics of 1.9 and 2.9 kcal/ molt. I-or the former rcacl~on the cross scctlon is backward

Quantum mechanica1 transition probabïlities have been calculated for the collinear reaction hfu + F~(u = 0) -+ MuF(u' G 3) + F by the state pa\*& sum method. The "best" extended LEPS surface no. 11 of Jonxthan et al. for the tl + F2 reaction bas been used. Approximately 40% of the available reaction

&I lbis paper are presented quantum mechanical I-initial and I-average cross sections and rate constants for the reactions: D + Hz(Ui = 0. 1) -HD(ur = 0. 1) + H. The calculations were done employing the iufiuile order sudden approximation It was found that the I-average total cross sections overlap

A close-coupling calculation of integral cross sections for the reaction F + Hz (u= 0, j= 0) +FH ( v'f ) + H has been performed in the threshold energy range using hyperspherical coordinates, The convergence of partial reaction probabilities with respect to a,, the maximum magnitude of the total ang

We report the first experimental and theoretical observation of a broad peak in the kinetic energy dependence of the total cross sections for the title reaction with v~ = 0 and 1, in the laboratory collision energy range of 8-400 eV. A theoretical analysis reveals that the peak in the total cross se