Molecular isotope effects in the thermal-energy charge exchange between He+ and N2

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.

The charge transfer reaction of He+ with N20 produces vibrationally excited N:(X) ions. The relaxation processes occurring after formation of the NC (X, u" ) ions have been investigated. Charge transfer with N,O is the main relaxation mechanism and its rate does not vary much with the internal energ

A model based on the two film approximation is proposed for the description of the kinetics of the hydrogen isotope exchange between CHCl3 and DzO. In this model, details of mass transfer in interfacial region between the two liquid phases are considered and the kinetics of the exchange reaction is

A laser fluorcscencr tcchniquc has been used to measure (Vv) cxchangc ratl?s between CO(u = 1) and t4Nz and l5 N, to GO K. At GS K exchsngc :o t 5Nz has 65 times the higher rate constant. Comparison with data for (VV) exchange in hquid N2 sllows that the isulatcd binary collision theory does not hol

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

The reaction C( 'P) +NsO(% \*C+) is studied by varying the kinetic energy of C(3P) in two center-of-mass regimes: 0.1-0.2 eV and 2-7 eV. C( 3P) is directly observed, and the C, velocity distribution is estimated from the time-of-flight of Cs. CN(X %+) is vibrationally inverted and rotationally 'hot'