Probing the basis set limit for thermochemical contributions of inner-shell correlation: Balance of core-core and core-valence contributions

TL;DR

This study evaluates the basis set limit for inner-shell correlation contributions to thermochemical energies, comparing different basis set families and their convergence behavior to optimize accuracy and computational efficiency.

Contribution

It systematically analyzes core-core and core-valence contributions using various basis sets, identifying optimal combinations for high-accuracy thermochemistry calculations.

Findings

aug-cc-pwCVTZ is superior for core-valence extrapolation

nZaPa-CV basis sets excel in core-core contributions

CCSD(T)/awCV{T,Q}Z offers a good accuracy-cost balance

Abstract

The inner-shell correlation contributions to the total atomization energies (TAEs) of the W4-17 computational thermochemistry benchmark have been determined at the CCSD(T) level near the basis set limit using several families of core correlation basis sets, such as aug-cc-pCVnZ (n=3-6), aug-cc-pwCVnZ (n=3-5), and nZaPa-CV (n=3-5). The three families of basis sets agree very well with each other (0.01 kcal/mol RMS) when extrapolating from the two largest available basis sets: however, there are considerable differences in convergence behavior for the smaller basis sets. nZaPa-CV is superior for the core-core term and awCVnZ for the core-valence term. While the aug-cc-pwCV(T+d)Z basis set of Yockel and Wilson is superior to aug-cc-pwCVTZ, further extension of this family proved unproductive. The best compromise between accuracy and computational cost, in the context of high-accuracy computational thermochemistry methods such as W4 theory, is CCSD(T)/awCV{T,Q}Z, where the {T,Q} notation stands for extrapolation from the awCVTZ and awCVQZ basis set pair. For lower-cost calculations, a previously proposed combination of CCSD-F12b/cc-pCVTZ-F12 and CCSD(T)/pwCVTZ(no f) appears to 'give the best bang for the buck'. While core-valence correlation accounts for the lion's share of the inner shell contribution in first-row molecules, for second-row molecules core-core contributions may become important, particularly in systems like P4 and S4 with multiple adjacent second-row atoms. The average absolute core-core/core-valence ratio is 0.08 for the first-row species in W4-17, but 0.47 for the second-row subset.