The charge transfer reaction Ar+ + N2 → N+2 + Ar. Crossed-beam measurements of the integral cross section as a function of the collision energy

A crossed beam study of the title reaction if reported, from 0.45 to 7.8 eV. The reaction is predominantly transkxtioionally endothermic. At the lowest energy, there is evidence for two reactlon paths: a long-range electron transfer and an titimate coihsion mth electron transfer. Branching ratios fo

A continuous, supersonic molecular beam is crossed at 90" with a radio-frequency guided ion beam in a tandem mass spectrometer. This experimental configuration makes possible measurements of the integral reactive cross-section as a functton ofcollision energy with a much higher energy resolution wit

Differential cross sectiona for the scattering of N3 (velocity selected beam) by Ar (nozzle beam) were measured at different kinetic energies in the range E = 7.73 -15.6 x lo-14 erg. r?om the rainbow scattering the well depths = 1.63 -L 0.15 x lo-14 erg has been deduced for an assumed L.-J. (I2.6) p

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

The reaction Ar+(2Pgn) + N,(X tzk,, u = 0) -Ar + Nt(X zag, u") was studred at 1.1 eV coU~~~on energy usmg a crossed-beam method. in contrast wrth results at higher and lower cok~on energtes. the scattenng diagram obtruned at thts energy exhtbtts clearly resolved structure whtch suggests that product