posted on 2024-10-08, 05:45authored bySteven R. Gwaltney
Coupled-cluster singles and doubles calculations with
perturbative
triples [CCSD(T)] offer high accuracy with significant cost. The standard
way to reduce the cost of a CCSD(T) calculation is by excluding molecular
orbitals from the correlated calculation. While this speeds up the
calculation, it also throws away the contribution from the inactive
orbitals to the correlation energy. Here, we propose extending the
standard CCSD(T) method to account for the effects of these inactive
orbitals. This approach is based on a perturbation expansion of the
similarity-transformed Hamiltonian, and the final method includes
external singles and doubles corrections along with a semi-internal
triples term. Compared to all-electron CCSD(T) calculations with the
cc-pCVTZ basis set for a set of small molecules, we recovered, on
average, 98% of the total correlation energy while using only 30%
of the molecular orbitals. Using 72% of the molecular orbitals gave
99.5% of the correlation energy.