| Abstract: | Total quenching of the low‐Rydberg state of Na in collision with thermal Ne and Ar was investigated, for the first time, employing a molecular approach in the impact parameter formalism. A large basis set of Slater‐type orbitals was used to calculate the molecular structure of the transient quasimolecule formed during the collision; pseudopotentials were used to incorporate the effective binding of the distant electron. A 14‐channel calculation was carried out to evaluate the total depopulation cross sections for Na(9s) colliding with the ground‐state Ne and Ar atoms in the thermal‐energy region. The two colliding pairs not only differ from each other, but also show wide variations from the previously studied Na He pair, in terms of details of the collision dynamics. In the case of the Na Ar system, a unique feature that leads to appreciably larger quenching cross sections shows qualitative agreement with the measurement. A comparative study of three (He/Ne/Ar Na) colliding pairs reveals that the simplified approach like the free‐electron model or the impulse approximation fails to provide details of such state‐changing reactions. ©1999 John Wiley & Sons, Inc. Int J Quant Chem 73: 307–316, 1999 |
