Abstract
Electrified solid-liquid interfaces play a crucial role in energy conversion, storage,
photoconversion, sensors, and corrosion processes. While computational chemistry simulations can provide detailed insight into reaction mechanisms, aligning experimental
and simulation results remains a significant challenge. In this work, we introduce the
FDT-SJM method for ab-initio molecular dynamics simulations under potential control,
where the electrode charge fluctuates around an average value following the fluctuationdissipation theorem (FDT), and electrode charges are screened by the solvated jellium
method (SJM). The FDT-SJM is developed in GPAW, a Python-based, open-source
DFT code. We validate this approach by simulating the Au(111) interface in pure water, KOH, LiOH, Li, and K solutions at several electrode potentials. We analyze water
reorientation in response to changes in the electrode surface charge and demonstrate
that the method enables the estimation of interface capacitance and the potential of
zero charge, yielding values consistent with experimental data.
Supplementary materials
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Supplemental Material
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Additional figures and supporting analysis
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