An experimental rate constant for H + H2 (ν″ = 1) → H + H2 (ν″ = 0)

## Anestimateoftherateconstant forthevibration-to-vibrationenergy transferprocess2Hz(v = I)-H2(~ = O)+ Hz& = 2) is made by analyzing the dependence of the effective rate of relaxation on the degee of laser excitation. At 82 K it is (6.3 f 2.1) X 1O-'6 cm3 molecule-t s-~.

The classical trajectory method is applied to calculate the total cross sectio.1 for the exchange reaction Hz(u = 1) + H = H + Hz\_ The vibrational excitation is shown to influence efficiently the tbresb~ld value. Partial reaction rate-constants calculated on the basis of the cross sections obtained

The rate constant for the reaction between OH and vibrationally excited H2, OH + H 2 (v = 1) ~ H20 + H, has been measured directly at 298 K. kol is found to be (7.5 -+ 3) X 10 -13 cma/molecule s, corresponding to a vibrational rate enhancement ofkol/koo = (1.2 -+ 0.4) X 102.

Total symmetric electron transfer cross secrions for state-selected Hz ions were measured for vibrational levels of the ion from u = 0 to 10 af a relative uanslational energy of 16 eV. The internal energ of the rz ions was selected by thresllold photoclccrron-photoion coincidence using pulsed synchr

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