Add to ORKGNatural collision coordinates and a zeroth‐order vibrational–adiabatic approximation are used to treat linear reactive collisions. Nonadiabatic effects on barrier transmission and on vibrational state of products are calculated. The present results are classical and are compared with exact classical numerical results for the H+H_2 reaction in the range 7–20 kcal/mol of initial relative translational energy. The agreement is encouraging and the results support the concepts introduced earlier of statistical adiabaticity and of nonadiabatic leak. At low energies the reaction is adiabatic on the average (initial vibrational phase average), thus justifying activated complex theory for this system. The relative importance of reaction path curvatu...
We have performed accurate quantum mechanical calculations for the coplanar H + H_2 exchange reacti...
We have performed accurate quantum mechanical calculations for the coplanar H + H_2 exchange reacti...
The coordinates of earlier papers of this series are extended from linear collisions to reactions in...
The classical mechanics of chemically reactive linear collisions is investigated for vibrationally n...
The analytical quantum mechanics of chemically reactive linear collisions is treated in the vibratio...
The analytical quantum mechanics of chemically reactive linear collisions is treated in the vibratio...
Rotational and vibrational distributions for the exchange reaction H+H_(2)→H_(2)+H are obtained nume...
The natural collision coordinates of Part III are used to treat the analytical mechanics of chemical...
The classical mechanics of chemically reactive linear collisions is investigated for vibrationally n...
Co-ordinates and "vibrationally-adiabatic" approximations are described for reactions in three dimen...
Co-ordinates and "vibrationally-adiabatic" approximations are described for reactions in three dimen...
The statistical—dynamical model formulated in Paper I is applied to the H+H_(2)→H_(2)+H reaction and...
Accurate three‐dimensional reactive and nonreactive quantum mechanical cross sections for the H+H_2 ...
We present numerical quantum mechanical scattering calculations for the collinear H+H2 reaction on a...
We have performed accurate quantum mechanical calculations for the coplanar H + H_2 exchange reacti...
We have performed accurate quantum mechanical calculations for the coplanar H + H_2 exchange reacti...
We have performed accurate quantum mechanical calculations for the coplanar H + H_2 exchange reacti...
The coordinates of earlier papers of this series are extended from linear collisions to reactions in...
The classical mechanics of chemically reactive linear collisions is investigated for vibrationally n...
The analytical quantum mechanics of chemically reactive linear collisions is treated in the vibratio...
The analytical quantum mechanics of chemically reactive linear collisions is treated in the vibratio...
Rotational and vibrational distributions for the exchange reaction H+H_(2)→H_(2)+H are obtained nume...
The natural collision coordinates of Part III are used to treat the analytical mechanics of chemical...
The classical mechanics of chemically reactive linear collisions is investigated for vibrationally n...
Co-ordinates and "vibrationally-adiabatic" approximations are described for reactions in three dimen...
Co-ordinates and "vibrationally-adiabatic" approximations are described for reactions in three dimen...
The statistical—dynamical model formulated in Paper I is applied to the H+H_(2)→H_(2)+H reaction and...
Accurate three‐dimensional reactive and nonreactive quantum mechanical cross sections for the H+H_2 ...
We present numerical quantum mechanical scattering calculations for the collinear H+H2 reaction on a...
We have performed accurate quantum mechanical calculations for the coplanar H + H_2 exchange reacti...
We have performed accurate quantum mechanical calculations for the coplanar H + H_2 exchange reacti...
We have performed accurate quantum mechanical calculations for the coplanar H + H_2 exchange reacti...
The coordinates of earlier papers of this series are extended from linear collisions to reactions in...