Potential curves for Na2+ and resonance charge transfer cross sections

A comparatively simple interpretation of the method of Firsov [Sov. Phys. JETP 21, 1001 (1951)] is used to calculate symmetric resonant charge transfer cross sections for the first 20 (nontransition) elements H through Ca in the range of low and intermediate collision velocities (£1.0 1 10 8 cm/s).

Total resonsnt charge-transfer cross sections of (Na+,No) and (K',K) collisions are calculated using atomic wavefunctions and model potentials within the framework of the impact parameter formalism in complete analogy with an earlier successful calculation concerning Rb and Cs atoms. In the present

Adiabatic potentia? curves and wavefunctions tie been calculated for ground and excited states of diatomic molecules formed from an alkali atom (Li, Na, K) and an alkali ion or rare gas atom (Li+, Naf, I<+, He, Ne, .&I. A model potential method has been used. The energies are believed to be reliable

Ionic products have been observed in collisions of alkali atoms an.1 halogen molecules in the eV region. The energy dependence of t.Ys total cross sections for ion-production has been measured for K, Na and Li on Br2 and a discussion of the results is given based on the Landau Zener formula.

Electronic transition moments and oscillator strengths for rhree valence transitions in Lig and in Nag have been computed as a function of internuclear distance using wavefunctions obtained from a model potential description. Band oscillator strengths and photodissociation cross sections for the X '

## Rekvcd I2 April 1984 CNDO/S computation on the H20-0, complex show stable triplet n -n+ charge transfer states at 8.8 nnd 10.0 cV.