Comparison of ab initio and experimentally determined torsional potentials of ethylene in the ground state

Hartree-Fock computations of the potential surface of Ar-H, have been carried out and supplemented with calculations of the dispersion energy, with use of the counterpoise method to remove the basis set superposition error. The collinear and perpendicular bisector geometries are considered. The resu

New experiments based on resonant multiphoton ionization spectroscopy have allowed the observation of Ar-NO and Ar-NO+ ground states. We present a new theoretical method, using a CIPSI approach, to calculate the ground state potential surfaces of X-NO+ complexes (X=He, Ar), which gives results in go

Llcctnc dlpole moment functions and radiahre tr;msiuon rates haw been calculated ior the X '~+state of BF and the Y z~\* swc oi BP irom MC SCF uavefunctlons. Both ale prcdickd to be strong emitters m the infrared. For BF\* the elcctromcally uvxed z~\* state. corrcspondmg to the coniigunuon lo' 2a'3

Ab initio SCF c&zulations using the generalized coupling operator method have been p&formed OR the ground and two excited states of methyl radical. Geometries of the ground and one excited state have been optimized. Vertical transition energies have also been calculated.