Abstract
We have recently developed the full and active-space doubly electron-attached (DEA) and doubly ionised (DIP) equation-of-motion coupled-cluster (EOMCC) methods with up to 4-particle–2-hole (4p-2h) and 4-hole–2-particle (4h-2p) excitations. By examining the low-lying singlet and triplet states of the methylene, (HFH)−, and trimethylenemethane biradicals, and a few different types of molecular orbitals (MOs) to describe the corresponding wave functions, including the restricted or restricted open-shell Hartree–Fock orbitals of the target N-electron species and their counterparts associated with the (N ∓ 2)-electron reference systems, we demonstrate that the DEA- and DIP-EOMCC approaches with the full and active-space treatments of 4p-2h and 4h-2p excitations provide high-accuracy results which are not only in perfect agreement with one another, but also practically insensitive to the choice of the underlying MO basis. This should be contrasted with the DEA- and DIP-EOMCC methods truncated at 3p-1h/3h-1p excitations, which are generally less accurate and more sensitive to the types of orbitals used in the calculations.
Acknowledgements
We dedicate this paper to Professor Rodney J. Bartlett. One of us (P. Piecuch) would like to thank Professors Hans-Peter Lüthi, Jürgen Gauss, Martin Head-Gordon, Henry F. Schaefer III, and John F. Stanton for inviting him to speak at the Molecular Quantum Mechanics 2013 (MQM 2013) Conference and Professor Martin Head-Gordon for encouraging us to submit an article for the MQM 2013 Special Issue of Molecular Physics in honour of Professor Rodney J. Bartlett. We thank Professor C. David Sherrill for providing us with the full CI results for the TZ2P model of methylene using the ROHF orbitals for the triplet ground state and the lowest energy RHF orbitals for the low-lying singlet excited states [Citation93].