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The quantum dynamics of electronically nonadiabatic chemical reactionsConsiderable progress was achieved on the quantum mechanical treatment of electronically nonadiabatic collisions involving energy transfer and chemical reaction in the collision of an electronically excited atom with a molecule. In the first step, a new diabatic representation for the coupled potential energy surfaces was created. A two-state diabatic representation was developed which was designed to realistically reproduce the two lowest adiabatic states of the valence bond model and also to have the following three desirable features: (1) it is more economical to evaluate; (2) it is more portable; and (3) all spline fits are replaced by analytic functions. The new representation consists of a set of two coupled diabatic potential energy surfaces plus a coupling surface. It is suitable for dynamics calculations on both the electronic quenching and reaction processes in collisions of Na(3p2p) with H2. The new two-state representation was obtained by a three-step process from a modified eight-state diatomics-in-molecules (DIM) representation of Blais. The second step required the development of new dynamical methods. A formalism was developed for treating reactions with very general basis functions including electronically excited states. Our formalism is based on the generalized Newton, scattered wave, and outgoing wave variational principles that were used previously for reactive collisions on a single potential energy surface, and it incorporates three new features: (1) the basis functions include electronic degrees of freedom, as required to treat reactions involving electronic excitation and two or more coupled potential energy surfaces; (2) the primitive electronic basis is assumed to be diabatic, and it is not assumed that it diagonalizes the electronic Hamiltonian even asymptotically; and (3) contracted basis functions for vibrational-rotational-orbital degrees of freedom are included in a very general way, similar to previous prescriptions for locally adiabatic functions in various quantum scattering algorithms.
Document ID
19940014364
Acquisition Source
Legacy CDMS
Document Type
Contractor Report (CR)
Authors
Truhlar, Donald G.
(Minnesota Univ. Minneapolis, MN, United States)
Date Acquired
September 6, 2013
Publication Date
April 9, 1993
Subject Category
Atomic And Molecular Physics
Report/Patent Number
NAS 1.26:194309
NASA-CR-194309
Accession Number
94N18837
Funding Number(s)
CONTRACT_GRANT: NCC2-526
Distribution Limits
Public
Copyright
Work of the US Gov. Public Use Permitted.
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