Key role of density functional approximation in predicting M-N-C catalyst activities for oxygen reduction

16 May 2024, Version 2
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Metal-Nitrogen-Carbon motifs present intriguing structural and electronic properties for a number of applications, including as oxygen reduction catalysts. However, computational investigations of M-N-C-catalyzed reactions have must grapple with their complex electronic structures. In the present study, we evaluate the impact of the density functional approximation on calculated M-N-C catalyst activities for oxygen reduction. Using metalloporphyrins as model catalysts, we find a significant split between pure (GGA) and hybrid functionals, with hybrid functionals, in particular B3LYP, showing greater agreement with DLPNO-CCSD(T) reaction energies. Notably, double-hybrids offered no noticeable improvement over the much more computationally efficient B3LYP and PBE0. Other discrepancies between functionals, including ground state spin and geometry, are also considered in this work. Finally, both hybrid and double-hybrid functionals greatly reduced the gas phase errors associated with the main group molecules in the oxygen reduction reaction relative to GGA calculations, leading us to question the application of widely used empirical corrections to O$_2$.

Keywords

Density Functional Theory
Oxygen Reduction Reaction
Computational Hydrogen Electrode
Benchmarking
Metalloporphyrin

Supplementary materials

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Description
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Title
Supplementary Information
Description
Additional computational details, methods, and materials, including volcano plot construction, benchmarking of DLPNO-CCSD(T), DLPNO-CCSD(T) spin splittings, and characterization of geometries and spin contamination.
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Computational Data
Description
Energies and geometry characterization for all structures.
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