Mayo Clinic, Scottsdale, AZ 85259, USA.
Chemphyschem. 2012 Dec 7;13(17):3981-8. doi: 10.1002/cphc.201200469. Epub 2012 Oct 11.
The density functional version of symmetry-adapted perturbation theory, SAPT(DFT), is a computationally efficient method for calculating intermolecular interaction energies. We evaluate its accuracy by comparison with experimentally determined noble gas interaction potentials and sublimation enthalpies, most of which have not been previously calculated using this method. In order to compare the results with wavefunction methods, we also calculate these quantities using MP2 and, for noble gas dimers, using CCSD(T). For the crystal lattice energy calculations, we include corrections to the dispersion, electrostatic, and induction energies that account for the finite interaction distance cutoff and higher-order induction contributions. Overall, the energy values extrapolated to the complete basis set limit show that SAPT(DFT) achieves significantly better agreement with experiment than MP2.
对称性自适应微扰理论的密度泛函版本(SAPT(DFT))是一种计算分子间相互作用能的计算效率高的方法。我们通过与实验测定的稀有气体相互作用势能和升华焓进行比较来评估其准确性,其中大部分势能和升华焓以前没有使用该方法进行计算。为了与波函数方法进行比较,我们还使用 MP2 计算了这些量,对于稀有气体二聚体,我们使用 CCSD(T) 计算。对于晶体晶格能计算,我们包括了对色散、静电和感应能的修正,这些修正考虑了有限的相互作用距离截止和高阶感应贡献。总的来说,外推到完全基组极限的能量值表明,SAPT(DFT)与实验的一致性显著优于 MP2。
