D. Feller et Ja. Sordo, A CCSDT study of the effects of higher order correlation on spectroscopic constants. I. First row diatomic hydrides, J CHEM PHYS, 112(13), 2000, pp. 5604-5610
Spectroscopic constants have been determined for 13 first row diatomic hydr
ides using coupled cluster theory with explicit inclusion of (iterative) tr
iple excitations (CCSDT). Comparison of the predicted dissociation energies
, bond lengths, harmonic frequencies, and anharmonicities was made with exp
eriment and other high-level theoretical treatments. These include complete
active space configuration interaction wave functions, coupled cluster the
ory with perturbative triples [CCSD(T)], and new benchmark full configurati
on interaction calculations. Excellent overall agreement with experiment wa
s found, even without correcting for small changes due to core/valence and
relativistic effects. The intrinsic CCSDT error with respect to experiment
for each molecule and property was estimated by extrapolating to the comple
te basis set limit. Among the various properties examined in this study, no
significant differences were found between CCSD(T) and CCSDT. In light of
the substantial increase in computational cost associated with the latter m
ethod, there appears to be little justification for selecting it over CCSD(
T) in studies of first row hydrides. Preliminary results for first row diat
omics, e.g., N-2, suggest that the impact of CCSDT will increase with the n
umber of electrons. (C) 2000 American Institute of Physics. [S0021-9606(00)
31513-6].