Approximate quantum differential cross sections for the F + H2 reaction

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

Product angular and velocity distributions for vibrationally state-selected ion-neutral reactions are measured wrth a new technique that uses resonantly enhanced multiphoton ionization and impulsive acceleration of reactant ions to achieve crossed-beam scattermg conditions in a single molecular beam

Our reactive-infinite-order-sudden-approximation (RIOSA) numerical procedure has been revisited to single out features relevant to the parallel restructuring. Speedups obtained on a shared-memory machine, after a restructuring aimed at exploiting both the temporal and spatial parallelism of the appr

Accurate reactive scattering calculations of integral cross sections for the reaction F+H, were carried out by utilizing the latest basis contraction techniques developed for the S matrix Kohn variational method. Convergence with respect to increasing the number of K states (K,,,,) for high J calcul

The statistical& approximation developed recently is extended to include drfferential cross sections. Two levels of the approximatlon are studied, both of which ledd to the same expressions for the statisticalIZ integral cross sections. The approach is illustrated by applications to He + HZ and He +