Direct calculation of resonant states in reactive scattering. Application to linear triatomic systems
- 1 April 1981
- journal article
- research article
- Published by Wiley in International Journal of Quantum Chemistry
- Vol. 19 (4) , 611-635
- https://doi.org/10.1002/qua.560190414
Abstract
A direct method for calculating resonant states in reactive scattering is suggested, permitting us to obtain the characteristics of multichannel resonances (partial width amplitudes). The method is based on the construction of a Laurent expansion of the scattering matrix S(ϵ −iΓ/2) in the complex plane. The position of the poles of the S matrix are derived by solving the dynamical problem with complex energy values. The residue at the pole gives all the information concerning the partial widths. The method is applied to a linear triatomic reactive scattering problem. The properties of the resonant states in the H + H2 system are calculated as an example. Two broad resonances are found which have not been reported in previous calculations. The interference of overlapping resonances is shown to have a profound effect on the energy dependence of the transition probabilities.Keywords
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