Publication date: Jun 15, 2022
Determining ab-initio potential dependent energetics are critical to investigating mechanisms for electrochemical reactions. While methodology for evaluating reaction thermodynamics is established, simulation techniques for the corresponding kinetics is still a major challenge owing to a lack of potential control, finite cell size effects or computational expense. In this work, we develop a model which allows for computing electrochemical activation energies from just a handful of Density Functional Theory (DFT) calculations. The sole input into the model are the atom centered forces obtained from DFT calculations performed on a homogeneous grid composed of varying field-strengths. We show that the activation energies as a function of the potential obtained from our model are consistent for different super-cell sizes and proton concentrations for a range of electrochemical reactions. This record contains output files from all the DFT calculations needed to reproduce the figures in the manuscript.
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File name | Size | Description |
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calculations.zip
MD5md5:1def374f08ae486a7597d969be19f011
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192.0 MiB | Output files of DFT calculations used to generate the figures in the manuscript. Note that a combination of DFT codes were used, and is demarcated by the folder names. NOTE: The folders contains pickle files generated by ASE v. 3.20 obtained during the vibrational calculations. |
2022.78 (version v1) [This version] | Jun 15, 2022 | DOI10.24435/materialscloud:p4-fj |