Orbital Optimization and Neural-Network-Assisted Configuration Interaction Calculations of Rydberg States
Abstract
Rydberg excited states of molecules pose a challenge for electronic structure calculations because of their highly diffuse electron distribution. Even large and elaborate atomic basis sets tend to underrepresent the long-range tail, overly confining the Rydberg state. An approach is presented where the molecular orbitals are variationally optimized for the excited state using a plane wave basis set in Hartree-Fock calculations, followed by configuration interaction calculations on the resulting reference. Using excited state optimized plane wave orbitals greatly enhances the convergence of the many-body calculation, as illustrated by a full configuration interaction calculation of the 2s Rydberg state of H$_2$. A neural-network-based selective configuration interaction approach is then applied to calculations of the 3s, 3p$_x$ and 3p$_y$ states of H$_2$O and the 3s and 3p$_z$ states of NH$_3$. The obtained values of excitation energy are in close agreement with experimental measurements as well as previous many-body calculations based on sufficiently diffuse atomic basis sets. Previously reported high-level calculations limited to atomic basis sets lacking extra diffuse functions, such as aug-cc-pVTZ, give significantly higher estimates due to confinement of the Rydberg states.