The ABC of Generalized Coordination Numbers and Their Use As a Descriptor in Electrocatalysis

Overview

Journal Adv Sci (Weinh)

Specialty Biomedical Engineering

Date 2023 Apr 27

PMID 37102632

Authors

Federico Calle-Vallejo

Affiliations

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Abstract

The quest for enhanced electrocatalysts can be boosted by descriptor-based analyses. Because adsorption energies are the most common descriptors, electrocatalyst design is largely based on brute-force routines that comb materials databases until an energetic criterion is verified. In this review, it is shown that an alternative is provided by generalized coordination numbers (denoted by or GCN), an inexpensive geometric descriptor for strained and unstrained transition metals and some alloys. captures trends in adsorption energies on both extended surfaces and nanoparticles and is used to elaborate structure-sensitive electrocatalytic activity plots and selectivity maps. Importantly, outlines the geometric configuration of the active sites, thereby enabling an atom-by-atom design, which is not possible using energetic descriptors. Specific examples for various adsorbates (e.g., *OH, *OOH, *CO, and *H), metals (e.g., Pt and Cu), and electrocatalytic reactions (e.g., O reduction, H evolution, CO oxidation, and reduction) are presented, and comparisons are made against other descriptors.

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