A density fitting scheme for the fast evaluation of molecular electrostatic potential
Yingfeng Zhang, Jian Zhao
Abstract
Abstract Molecular electrostatic potential (MEP) is a significant and crucial physical quantity that can be applied to a large number of scenarios, such as the prediction of nucleophilic or electrophilic attacks, fitting atomic charges, σ‐hole, and so forth. The computational cost for the MEP has an O ( N 2 ) scaling with the increase of atoms, which is intractable and laborious for macromolecules. Herein, a density fitting molecular electrostatic potential (DF‐MEP) is used to reduce the computational costs for the macromolecular MEP. It is found that the accuracy of DF‐MEP is almost identical to the conventional molecular electrostatic potential (Conv‐MEP), while the computational costs can be reduced to an O ( N ) scaling, for example, the computational time of 699,200 grids for the Trp‐cage molecule (304 atoms) only takes 16.6 s at the B3LYP‐D3(BJ)/def2‐SVP level of theory with 16 CPU cores compared with 3060.2 s for the Conv‐MEP method.