Machine Learning-Aided First-Principles Calculations of Redox Potentials

TL;DR

This paper combines first-principles calculations with machine learning techniques to accurately predict redox potentials of metal ions, addressing longstanding computational challenges in electrochemistry.

Contribution

It introduces a novel hybrid approach integrating machine learning with thermodynamic methods to improve redox potential predictions using hybrid functionals.

Findings

Predicted redox potentials closely match experimental values.

The method reduces computational cost for hybrid functional calculations.

Achieves statistically accurate redox potential estimates.

Abstract

Redox potentials of electron transfer reactions are of fundamental importance for the performance and description of electrochemical devices. Despite decades of research, accurate computational predictions for the redox potential of even simple metals remain very challenging. Here we use a combination of first principles calculations and machine learning to predict the redox potentials of three redox couples, $\mathrm{Fe}^{2+}$/$\mathrm{Fe}^{3+}$, $\mathrm{Cu}^{+}$/$\mathrm{Cu}^{2+}$ and $\mathrm{Ag}^{+}$/$\mathrm{Ag}^{2+}$. Using a hybrid functional with a fraction of 25\% exact exchange (PBE0) the predicted values are 0.92, 0.26 and 1.99 V in good agreement with the best experimental estimates (0.77, 0.15, 1.98 V). We explain in detail, how we combine machine learning, thermodynamic integration from machine learning to semi-local functionals, as well as a combination of thermodynamic perturbation theory and $\Delta$-machine learning to determine the redox potentials for computationally expensive hybrid functionals. The combination of these approaches allows one to obtain statistically accurate results.