Quantum-mechanical calculation of integral cross sections for the reaction F+H2(v=0, j=0)→FH(v′ j′)+H by the hyperspherical method

in final form 17 Jzmuxy 19S3 \'elocrf~ -scatterms angle intenslty mqs for the 1: + Il,(u = O;] = 0) -1'11( r: = 1.3; j') + II reaction are predicted from ~1rr~ntur"-nrcclranic~l I\_-consening calculations. The extent of the s/xi/r in the angular distribution from barksntteriq at 1-S hc.d,!molr 10 si

Integral reactive quantum-mechanIcal cross secfions and product vibrational dlstriiuhons are presented for the r + Hz system. The calculations were made within the mfmite order sudden approximahon (IOSA) formahsm and the results are compared wllh expenmental data and results obtamcd with other treat

Integral and differential state-resolved cross sections have been calculated by the method of quasiclassical trajectories for the H t D,+HD+D reaction in the range of initial conditions of interest to recent experiments. When possible, the results are compared to exact quantum-mechanical calculation

Differentialandtotal state-to-state~sssectionsfoortheD+H,(u=O,j=O-3)~HD(u',j')+Hreactioninthe0.35-1.10eV collision energy range, have been calculated on the UTH surface using the QCT method. The results are commented on and compared to recent quantum mechanical calculations and to experimental measu

Based on an activation model, a available scheme to calculate the rate of the electron-transfer reaction between transition-metal complexes in aqueous solution is presented. Ab initio technique is used to determine the electron-transfer reactivity of the type M(H 2 O) 2+/3+ 6 of transition-metal com