TY - JOUR
T1 - Monte Carlo trajectories
T2 - Dynamics of the reaction F +D2 on a semiempirical valence-bond potential energy surface
AU - Biais, Normand C.
AU - Truhlar, Donald G
PY - 1973
Y1 - 1973
N2 - A semiempirical valence-bond calculation was carried out for the potential energy surface of H2F treating explicitly seven valence electrons (The integrals were evaluated from diatomic potential energy curves using the Cashion-Herschbach method. Using this potential energy surface, the chemical reaction F+D2-FD+D was studied by Monte Carlo calculations of quasiclassical trajectories. Crosssection calculations were carried out for initial conditions in these ranges: relative translational energy, 1.56-19.3 kcal/mole; rotational angular momentum (in units of h), 0-5; vibrational quantum number, 0-1. In addition, distributions of internal energy and scattering angles for the molecular product were calculated. The results were compared with those of previous theoretical studies and the comparison indicates that subtle features (not. well understood) of the potential surface may be important for obtaining correct results. The results were also compared with molecular beam, chemical laser, and infrared chemiluminescence results. The angular distributions are not accurate but the product internal energy distributions are in fairly good agreement with experiment. For the reaction F+Hz->FH+H, a limited number of trajectories were carried out for initial vibrational quantum numbers 0-3.
AB - A semiempirical valence-bond calculation was carried out for the potential energy surface of H2F treating explicitly seven valence electrons (The integrals were evaluated from diatomic potential energy curves using the Cashion-Herschbach method. Using this potential energy surface, the chemical reaction F+D2-FD+D was studied by Monte Carlo calculations of quasiclassical trajectories. Crosssection calculations were carried out for initial conditions in these ranges: relative translational energy, 1.56-19.3 kcal/mole; rotational angular momentum (in units of h), 0-5; vibrational quantum number, 0-1. In addition, distributions of internal energy and scattering angles for the molecular product were calculated. The results were compared with those of previous theoretical studies and the comparison indicates that subtle features (not. well understood) of the potential surface may be important for obtaining correct results. The results were also compared with molecular beam, chemical laser, and infrared chemiluminescence results. The angular distributions are not accurate but the product internal energy distributions are in fairly good agreement with experiment. For the reaction F+Hz->FH+H, a limited number of trajectories were carried out for initial vibrational quantum numbers 0-3.
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M3 - Article
AN - SCOPUS:36849105537
SN - 0021-9606
SP - 890
EP - 895
JO - The Journal of chemical physics
JF - The Journal of chemical physics
ER -