Ground state geometry of cinso

Ab $itio mol&xhr orbital calqdations predict an planar geometry for the ground state ofAIa3. l work done during SPS's leave .at Word.

Ab imtm LCAO hf0 SCI-calculations ~\lth DZ + 3d(S) base iunctmns show timt tlw sulphur trdluor~de radml ts :! ,313 nar n-mdml fwing a '8, ground smtc. L&x CIF,, 11 has an umbrcU~-structurc Howcwr. it bccomcs Y-sluped m 11s first 'At nated state which Ins been calculated to he only =?.-I eV dbow the

The electronic ground state of Ne~" is studied by multireference conf'lguration interaction calculations. This includes the compotation of potential energy surfaces for C®v and C,v geometries and potential energy curves for the diatomic ion Ne~" (2Z~+). In contrast to the situation for He~" and Ar~,

## Abstract A method for computing second‐order multiconfigurational perturbation theory (CASPT2) energy gradients numerically has been implemented and applied to a range of elementary organic chromophores, including 1,3 butadiene, acrolein, and two protonated Schiff bases. Geometries of ground and