%0 Journal Article %A Šimová, Lucia %A Řezáč, Jan %A Hobza, Pavel %D 2013 %T Convergence of the Interaction Energies in Noncovalent Complexes in the Coupled-Cluster Methods Up to Full Configuration Interaction %U https://acs.figshare.com/articles/journal_contribution/Convergence_of_the_Interaction_Energies_in_Noncovalent_Complexes_in_the_Coupled_Cluster_Methods_Up_to_Full_Configuration_Interaction/2387974 %R 10.1021/ct4002762.s001 %2 https://acs.figshare.com/ndownloader/files/4027666 %K CI calculations %K iterative pentuple excitations %K noncovalent interactions %K CCSD %K error compensation %K interaction energy %K spectroscopic accuracy %K method %K Noncovalent Complexes %K interaction energies %K Interaction Energies %K convergence %K electron complexes %K CCSDTQ %K CCSDTQP %K CC expansion %K CCSDT %X The CCSD­(T) method stands out among various coupled-cluster (CC) approximations as the “golden standard” in computational chemistry and is widely and successfully used in the realm of covalent and noncovalent interactions. The CCSD­(T) method provides reliable interaction energies, but their surprising accuracy is believed to arise partially from an error compensation. The convergence of the CC expansion has been investigated up to fully iterative pentuple excitations (CCSDTQP); for the smallest eight electron complexes, the full CI calculations have also been performed. We conclude that the convergence of interaction energy at noncovalent accuracy (0.01 kcal/mol) for the complexes studied is reached already at CCSDTQ or CCSDT­(Q) levels. When even higher accuracy (spectroscopic accuracy of 1 cm–1, or 3 cal/mol) is required, then the noniterative CCSDTQ­(P) method could be used. %I ACS Publications