Rotational energy transfer in the rigid-rotor CO2-Ar system and the energy dependence of the parameters of the power-gap law

Rate constants for the charge transfer reactions of Ar+ (2P,,2 ) with Ox and CO have been measured as a function of average center-of-mass kinetic energy ( KEcm) at three temperatures: 93,300 and 543 K. The rate constants for both reactions were found to be slow at room temperature and to decrease w

WC h.vc mvcst~zrcd the dependence of rhc clcc~ronw I-actor III clccuon-tnnsfccr ra,e const.~nlr on tic cnmw gap and tcmpualurc by minimizing the clcctronic cncrgy wilh rcspcc~ to the mstanbncous non-equdbrmm solvent polar~~t~on. The clcctronic charge billows out and shrinks III rhc "normal" and slro

An improved ion beam apparatus is used to study the nascent state distribution of products m the Ar+ + N, charge transfer reaction at 0.28 eV collision energy. The rotational distribution of the minor v = 0 vibrational channel under single-collision conditions can be characterized by ,a Boltzmann di

## Abstract An approximate analytical solution of relaxation in a low‐pressure system with exponential transition probabilities is given for vibrational–rotational energy transfer in the dissociation of diatomics. The main assumption is that the rotational degrees of freedom are in thermal equilibr

Rate constants for vibrational energy transfer have been measured in the system N2( v= 1) +CO( u= 0) as a function of energy mismatch by using isotopic derivatives of N2 and of CO. These rate constants have been determined both in the gas phase and in liquid argon solution at 8 5 K. For non-resonant

Previous kinematic analysis of the charge-ttnnsfer reaction of Ar+ with Na has shown an energy window near I eV collision energy where quantum-specific and angular-specific scattering is observed. Reactant energy and angular distributions were used to determine the center-of-mass energy distribution