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Abstract
The use of oriented external electric fields (OEEFs) as a potential tool for catalyzing chemical
reactions has gained traction in recent years. Electronic structure calculations using OEEFs are
commonly done using methods based on density functional theory (DFT), but until now, the
performance of DFT methods for calculating molecules in OEEFs had not been assessed in a more
general scope. Looking at the accuracy of both molecular geometries and electronic energies, we
have investigated a wide variety of density functionals using different basis sets to determine how
well the individual functionals perform on various types of chemical bonds. We found that most
functionals accurately calculate geometries in OEEFs, and that small basis sets are sufficient in
many cases. Calculations of electronic energies show a significant error introduced by the OEEF,
which the use of a larger basis set helps mitigate. Our findings show that DFT methods can be
used for accurate calculations in OEEFs, allowing researchers to make full use of the advantages
that they bring.
Supplementary materials
Title
Supporting Information
Description
Additional calculations showing performance using the cc‑pVTZ basis set and performance comparisons between various electronic structure methods
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