Adiabatic Approximation in Explicit Solvent Models of RedOx Chemistry

Author(s)

Vaissier, Valerie; Van Voorhis, Troy

Abstract

We propose a calculation scheme that accelerates QM/MM simulations of solvated systems. This new approach is based on the adiabatic approximation whereby the solute degrees of freedom are separated from those of the solvent. More specifically, we assume that the solute electron density remains constant with respect to the relaxation of the solvent molecules. This allows us to achieve a dramatic speed-up of QM/MM calculations by discarding the slow self-consistent field cycle. We test this method by applying it to the calculation of the redox potential of aqueous transition metal ions. The root-mean-square deviation (RMSD) between the full solvation and adiabatic approximation is only 0.17 V. We find a RMSD from experimental values of 0.32 V for the adiabatic approximation as compared to 0.31 V for the full solvation model, so that the two methods are of essentially the same accuracy. Meanwhile, the adiabatic calculations are up to 10 times faster than the full solvation calculations, meaning that the method proposed here reduces the cost of QM/MM calculations while retaining the accuracy.

Date issued

2016-09

URI

http://hdl.handle.net/1721.1/115111

Department

Massachusetts Institute of Technology. Department of Chemistry

Journal

Journal of Chemical Theory and Computation

Publisher

American Chemical Society (ACS)

Citation

Vaissier, Valérie and Troy Van Voorhis. “Adiabatic Approximation in Explicit Solvent Models of RedOx Chemistry.” Journal of Chemical Theory and Computation 12, 10 (September 2016): 5111–5116 © 2016 American Chemical Society

Version: Author's final manuscript

ISSN

1549-9618

1549-9626