Optimized RVB states of the 2-d antiferromagnet: ground state and excitation spectrum

## 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

The rotational spectrum of the ground state, the excited \(A\) states \(\nu_{3}, 2 \nu_{3}\) and probably \(\nu_{2}\), and the lowest \(E\) state \(v_{6}\) of \(\mathrm{CH}^{35} \mathrm{Cl}_{3}\) have been measured. The ground state microwave spectrum was analyzed to obtain nuclear quadrupole coupli

The ground state and low-lying states of MgH: are studied at the complete-active-space self-consistent-field and multireference configuration-interaction levels of theory. The binding energies of the \*I& and 2B2 states (relative to their asymptote) are significantly larger than that of the \*A, gro

## 2000) 55] has been performed with the WatsonÕs Hamiltonian up to sextic terms but shows some limits due to the A and S reductions. Since SO 2 F 2 is a quasi-spherical top, it can also be regarded as derived from an hypothetical XY 4 molecule. Thus we have developed a new tensorial formalism in