Kinetics of the reaction OH + D → OD + H

The kinetics of the reactions OH ϩ Br 2 : HOBr ϩ Br (1) and OD ϩ Br 2 : DOBr ϩ Br (3) have been studied in the temperature range 230-360 K and at total pressure of 1 Torr of helium using the discharge-flow mass spectrometric method. The following Arrhenius expressions were obtained either from the k

Guided-ion beam methods were used to measure the absolute cross sections for OH+/OD + derived from O + and H20/D20 collisions over the range of 0.25-20 eV relative energy. The cross sections for the isotopic homologues have the same form, a bimodal behavior that appears to be related to the thermoch

State-resolved integral and differential cross sections and product energy partitioning have been calculated for the reaction O(JD) + HD(v = 0, j = 0-1) ~ OH(OD) + D(H) by means of quasi-classical trajectory (QCT) calculations at a collision energy of 0.197 eV (19 kJ mol -~ ) using the potential ene

Rate coefficient expressions for O+H,-+OH+H (5H) and O+D+OD+D (5D) over the temperature ranges 1600-2250 and 2370-3390 K, respectively, of &,=3.7x 10L4exp( -65 k.l/RT) and k5~=4.7~ lO'\*exp( -74 kJ/RT) cm3 mol-' s-i were derived from laser absorption spectroscopic measurements in shock-heated H2-02-

We present a quasiclassical trajectory study of H + HOD ( v,, ul, Y, ) with an emphasis on how the reaction cross section and the branching between OH and OD products varies with the initial vibrational state of HOD and with relative translational energy. Comparison of the results for initial states