A Polarizable QM/MM Explicit Solvent Model for Computational Electrochemistry in Water

Author(s)

Wang, Lee-Ping; Voorhis, Troy Van

Abstract

We present a quantum mechanical/molecular mechanical (QM/MM) explicit solvent model for the computation of standard reduction potentials E[subscript 0]. The QM/MM model uses density functional theory (DFT) to model the solute and a polarizable molecular mechanics (MM) force field to describe the solvent. The linear response approximation is applied to estimate E[subscript 0] from the thermally averaged electron attachment/detachment energies computed in the oxidized and reduced states. Using the QM/MM model, we calculated one-electron E[subscript 0] values for several aqueous transition-metal complexes and found substantially improved agreement with experiment compared to values obtained from implicit solvent models. A detailed breakdown of the physical effects in the QM/MM model indicates that hydrogen-bonding effects are mainly responsible for the differences in computed values of E[subscript 0] between the QM/MM and implicit models. Our results highlight the importance of including solute–solvent hydrogen-bonding effects in the theoretical modeling of redox processes.

Date issued

2012-01

URI

http://hdl.handle.net/1721.1/76274

Department

Massachusetts Institute of Technology. Department of Chemistry

Journal

Journal of Chemical Theory and Computation

Publisher

American Chemical Society (ACS)

Citation

Wang, Lee-Ping, and Troy Van Voorhis. “A Polarizable QM/MM Explicit Solvent Model for Computational Electrochemistry in Water.” Journal of Chemical Theory and Computation 8.2 (2012): 610–617.

Version: Author's final manuscript

ISSN

1549-9618

1549-9626