posted on 2020-02-03, 16:28authored byZachary
K. Goldsmith, Maxim Secor, Sharon Hammes-Schiffer
Electric fields control
chemical reactivity in a wide range of
systems, including enzymes and electrochemical interfaces. Characterizing the electric fields
at electrode–solution interfaces is critical for understanding
heterogeneous catalysis and associated energy conversion processes.
To address this challenge, recent experiments have probed the response
of the nitrile stretching frequency of 4-mercaptobenzonitrile (4-MBN)
attached to a gold electrode to changes in the solvent and applied
electrode potential. Herein, this system is modeled with periodic
density functional theory using a multilayer dielectric continuum
treatment of the solvent and at constant applied potentials. The impact
of the solvent dielectric constant and the applied electrode potential
on the nitrile stretching frequency computed with a grid-based method
is in qualitative agreement with the experimental data. In addition,
the interfacial electrostatic potentials and electric fields as a
function of applied potential were calculated directly with density
functional theory. Substantial spatial inhomogeneity of the interfacial
electric fields was observed, including oscillations in the region
of the molecular probe attached to the electrode. These simulations
highlight the microscopic inhomogeneity of the electric fields and
the role of molecular polarizability at electrode–solution
interfaces, thereby demonstrating the limitations of mean-field models
and providing insights relevant to the interpretation of vibrational
Stark effect experiments.