Self-interaction error overbinds water clusters but cancels in structural energy differences

• Published in: Proceedings of the National Academy of Sciences - PNAS Vol. 117; no. 21; pp. 11283 - 11288
• Main Authors: Sharkas, Kamal, Wagle, Kamal, Santra, Biswajit, Akter, Sharmin, Zope, Rajendra R., Baruah, Tunna, Jackson, Koblar A., Perdew, John P., Peralta, Juan E.
• Format: Journal Article
• Language: English
• Published: United States National Academy of Sciences 26.05.2020
• Subjects: Binding energy; Clusters; CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY; Density; density functional theory; Energy; Error correction; Hexamers; INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY; Isomers; Mathematical analysis; Physical Sciences; self-interaction correction; Thermodynamics; water; Water chemistry; SCAN meta-GGA; DFT; self-interaction; water; hydrogen bond
• ISSN: 0027-8424; 1091-6490
• DOI: 10.1073/pnas.1921258117

We gauge the importance of self-interaction errors in density functional approximations (DFAs) for the case of water clusters. To this end, we used the Fermi–Löwdin orbital self-interaction correction method (FLOSIC) to calculate the binding energy of clusters of up to eight water molecules. Three representative DFAs of the local, generalized gradient, and metageneralized gradient families [i.e., local density approximation (LDA), Perdew– Burke–Ernzerhof (PBE), and strongly constrained and appropriately normed (SCAN)] were used. We find that the overbinding of the water clusters in these approximations is not a densitydriven error. We show that, while removing self-interaction error does not alter the energetic ordering of the different water isomers with respect to the uncorrected DFAs, the resulting binding energies are corrected toward accurate reference values from higher-level calculations. In particular, self-interaction–corrected SCAN not only retains the correct energetic ordering for water hexamers but also reduces the mean error in the hexamer binding energies to less than 14 meV/H₂O from about 42 meV/H₂O for SCAN. By decomposing the total binding energy into manybody components, we find that large errors in the two-body interaction in SCAN are significantly reduced by self-interaction corrections. Higher-order many-body errors are small in both SCAN and self-interaction–corrected SCAN. These results indicate that orbital-by-orbital removal of self-interaction combined with a proper DFA can lead to improved descriptions of water complexes.