# Engineering Three-Dimensional (3D) Out-of-Plane Graphene Edge Sites for   Highly-Selective Two-Electron Oxygen Reduction Electrocatalysis

**Authors:** Daniel San Roman, Dilip Krishnamurthy, Raghav Garg, Hasnain, Hafiz, Noel Nuhfer, Venkatasubramanian Viswanathan, Tzahi, Cohen-Karni

arXiv: 1904.04946 · 2020-07-07

## TL;DR

This paper reports a novel 3D graphene-based electrocatalyst with highly selective two-electron oxygen reduction, achieved through precise edge site engineering, spectroscopic analysis, and theoretical modeling, advancing hydrogen peroxide synthesis.

## Contribution

It introduces a nanowire-templated 3D fuzzy graphene catalyst with tunable edge sites, combining synthesis, spectroscopy, and simulations for improved active site understanding.

## Key findings

- NT-3DFG exhibits high selectivity (93%) for H2O2 production.
- Edge sites are functionalized by C=O and C-OH groups under alkaline conditions.
- A geometric descriptor predicts activity within ~0.1 V of computed values.

## Abstract

Selective two-electron oxygen reduction reaction (ORR) offers a promising route for hydrogen peroxide synthesis, and defective sp2 carbon-based materials are attractive, low-cost electrocatalysts for this process. However, due to a wide range of possible defect structures formed during material synthesis, identification and fabrication of precise active sites remain a challenge. Here, we report a graphene edgebased electrocatalyst for two-electron ORR - nanowire-templated three-dimensional fuzzy graphene (NT3DFG). NT-3DFG exhibits excellent efficiency (onset potential of 0.79 $\pm$ 0.01 V versus RHE), selectivity (93 $\pm$ 3 % H2O2), and tunable ORR activity as a function of graphene edge site density. Using spectroscopic surface characterization and density functional theory calculations, we find that NT-3DFG edge sites are readily functionalized by carbonyl (C=O) and hydroxyl (C-OH) groups under alkaline ORR conditions. Our calculations indicate that multiple site configurations at both armchair and zigzag edges may achieve a local coordination environment that allows selective, two-electron ORR. We derive a general geometric descriptor based on the local coordination environment that provides activity predictions of graphene surface sites within ~0.1 V of computed values. Herein we combine synthesis, spectroscopy, and simulations to improve active site characterization and accelerate carbon-based electrocatalyst discovery.

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Source: https://tomesphere.com/paper/1904.04946