Ab initio SOS CI calculations of the effect of internal rotation on the nmr parameters of H2O2

The energy v&es of the Io\\est "22 Feshbach resonzmce in rbe I l-15 eV region nre cafculnted m a rel~t~~ef~ smdI but carefully optimized ST0 basis set. ;\dd%ional information is obt.Gncd for the Z& rescxnant state. The dominnnt configuretions in the nsvefunctions are given.

The heights of the rotational barriers of the ditelluride bridge in H 2 Te 2 and (CH 3 ) 2 Te 2 have been calculated at the Hartree-Fock level with the 3-21G basis set. The minima in the rotational potential energy functions occur at torsional angles of 87.58Њ and 89.32Њ, respectively. The barriers

The Be2+-Hz0 system has been taken as an example in order to investigate the changes induced in water molecules on coordination. Pronounced changes in water geometry and vibrational frequencies are found. Optimised geometries of Bez+-water complejres are presented.

The geometrical structure, electronic states and g-tensor values of the hydrated Cu 2+ ion, [Cu(H20)6] 2+ complex, have been studied by means of ab initio MO and MRSDCI methods. The ground state potential energy surface calculated as functions of the axial and equatorial Cu-O bond distances (rax and

The potential-energy curves of internal rotation were calculated for 1,3-butadiene at the MP2r6-311G UU level, for isoprene and 1,3-pentadiene at the MP2r6-311G U level, and for 2,3-dimethyl-1,3-butadiene and styrene at the MP2r6-31G U level. Ž . Ž . The geometries of the energy minima stable confo