Excited states and electronic spectrum of ferrocene

The clectran-impact ener&y-loss spectrum of ketene has been measured at impact energics of 30 CV end 50 cV, and SGI~tering angles varying from 5" to 80". Transitions hzvc been observed at 3.7.5.3, and 5.86 cV. These values are in excellent agreement with recent high quality ab initio calculations. T

The results of ab initio SCF and CI calculations on the electronic states of NiCO are reported. The 'X+ ground state is a mixture of two primary configurations associated with the Ni 3d" and 3d94s states, and is bound by 18 kcal mol-' with respect to Ni and CO at R N,C = 1.77 A. The excited states (

The energies of the states below 40000 cm-' have been calculated at the CASPTZ( 3, 8)/ANO level. The symmetry assignments and energies at this level are: 2AI 15798 cm-', 2B2 21791 cm-', 4B, 27528 cm-', 2A, 40304 cm-', 2BI 41596 cm-', and 4A2 46879 cm-'. We expect these energies to be within 1500 cm-

Raman scattering transitions between the excited states 8( 'E) and 2A(rE) of Cr3+ in A1203 are studied. The new technique for population decay measurements of the excited states uses a pulsed tunable dye laser as an optical pump and a cw laser as a Raman probe, plus a gated detection system. The pop

The alX+-X3II separation is estimated to be 1804-110 cm -m, which is in reasonable agreement with the recent experimental determination that the separation in a neon matrix is between 15 and 182 cm-I. Th~ calculated spectroscopic constants for the excited states confirm the experimental assignment f

It is shown that if the absorption and luminescence spectra are normalized to the integrals of tJu and IJu3, respectively, the intersection point will generally correspond to the difference of the free energy of the system in the ground and in the excited states. Knowing the free-energy difference,