Photodissociation of the dimer ions Ar+2, Ne+2, and (CO2)+2

Collisional deactivation rate constants of CO+ A 'fI(v=O and 2) by He, Ne. Ar, N,, and CO have been determined by using a time-resolved laser-induced fluorescence technique. The results were combined with the previously determined Y= 1 rate constants to obtain an interesting u dependence of the rate

intramoleculv vibration--vibration energy transfer cross sections ha--e been calculated for COs(OO" 1) -I-Ne and COa(OO" 1) + COa (OOOO) over the tempemture range 100-3000 K. It is shown that (00'1) + (11'0) is the most important process at lower temperatures, while (00'1) + (10'0) dominates others

Collisional deactivation processes of the CO\* A 2TI( u= I ) state are investigated by a time-resolved laser-induced fluorescence technique.Theoverallquenchingrateconstantsaredeterminedtobe (9.lfl.O)xlO-", (1.3~0.1)~10-", (1.1~0.1)~10-9, (1.9+ 0.1 )X 10m9, and (1.5 kO.1) X 10m9 cm' molecule-' s-',

We describe a new ion source in which a nozzle beam of neutral molecules is ionised by an electron beam and the resulting molecular ion beam is studied by microwave spectroscopic methods. This ionisation technique results in significant population of the near-dissociation levels of the molecular ion

Ni,Ar+ ions generated in a laser-driven plasma/supersonic expansion are photodissociated at different photon energies. This weakly bound ion fragments into primarily Ni: ( +Ar) at 3.0 eV and into Ni' (+Ni t Ar) at 3.5 eV indicating the Ni-Ni+ bond dissociation energy is between these limits.