📝 SummarXiv

Abstract

In this work, we present frozen natural orbital (FNO) based implementations of equation-of-motion (EOM) coupled-cluster (CC) with singles, doubles, and triples (SDT) for ionization potential (IP), double ionization potential (DIP), electron attachment (EA), and double electron attachment (DEA) variants. For EOM-CC with singles and doubles (SD), the FNO approach has already been studied by Krylov and co-workers for IP variant and for spin-flipping and spin-conserving excited states (respectively, the SF and EE variants) for both total energies and energy-gaps. Recently, we presented FNO-CCSDT performance for ground state energies of molecules, triplet-singlet gaps and for numerical estimation force constants of some diatomic molecules. Now we present our study on performance of IP, DIP, EA and DEA variants of FNO-EOM-CCSDT in computing total-energies, and for target-reference and target-target energy-gaps. Following earlier studies by us and by Krylov and co-workers, we also present the XFNO-EOM-CCSDT approach for these variants and examine its performance for total energies and energy-gaps.