posted on 2020-11-09, 06:04authored byAdam Rettig, Diptarka Hait, Luke W. Bertels, Martin Head-Gordon
The
practical utility of Møller–Plesset (MP) perturbation
theory is severely constrained by the use of Hartree–Fock (HF)
orbitals. It has recently been shown that the use of regularized orbital-optimized
MP2 orbitals and scaling of MP3 energy could lead to a significant
reduction in MP3 error [Bertels, L. W.; J. Phys. Chem. Lett. 2019, 10, 4170 4176]. In this work, we examine whether density
functional theory (DFT)-optimized orbitals can be similarly employed
to improve the performance of MP theory at both the MP2 and MP3 levels.
We find that the use of DFT orbitals leads to significantly improved
performance for prediction of thermochemistry, barrier heights, noncovalent
interactions, and dipole moments relative to the standard HF-based
MP theory. Indeed, MP3 (with or without scaling) with DFT orbitals
is found to surpass the accuracy of coupled-cluster singles and doubles
(CCSD) for several data sets. We also found that the results are not
particularly functional sensitive in most cases (although range-separated
hybrid functionals with low delocalization error perform the best).
MP3 based on DFT orbitals thus appears to be an efficient, noniterative O(N6) scaling wave-function
approach for single-reference electronic structure computations. Scaled
MP2 with DFT orbitals is also found to be quite accurate in many cases,
although modern double hybrid functionals are likely to be considerably
more accurate.