Energy transfer in Ne and Xe collisions with CO2 at 1 eV

A many-body approach to motecuhr collisions is applied to the L~icuhtion of vibrational-rotational transition probtlbilities of ionsstztttered from linear triztomic molecules\_ The system Li+-CO2 has been chosen in order to comprtre the theoretical predictions with e..perimental resultr Good amment

possibk RSSOIIS for the non-monotonous tempa-aturs dependencf oE the q~~~d-rescmzm~~ emcrgy trmsf'er probability and relative contributions of short-range and long-range forces are discussed. Particular calcuhtions are made for the caze Nz-C02(v3) vibrational energy exchange.

Iodine molecules in su~msonic barns were collided with a single crystal 3lgO(lOO) surface. The dissociation probabilities and the kinetic ener~+s of the non-dissociated molecules were measured in the collision ener,v range I-10 eV and compared lvith the rcsuits of classical trajectory models. Very l

The charge-transfer reactions of He: with Kr and Xe at thermal energy have been studied in a helium afterglow. The relative populations of the product Kr+ (2P,,z,,,) and Xe+ ('P 3,2,1,2) spin-orbit states were determined by using state-selective formation of rare gas halide excimen from ion-recombin

Complete quantum state distributions for HD (u= 1) and HD(u=2) are obtained by photolyzing HI at 266 nm m the presence of D2 and detecting the nascent HD product via (2+ 1) resonance-enhanced multiphoton ionization (REMPI). Calibration against an effusive oven source ( d 1800 K) yields any necessary