What question did this study set out to answer?

This research aims to enhance the performance of oxygen evolution reaction catalysts for water electrolysis by improving stability and activity.

June 14, 2026

Ultrastable Non‐Noble‐Metal Oxygen Evolution Electrocatalyst for Industrial‐Level Water Electrolysis

Key Points

This research aims to enhance the performance of oxygen evolution reaction catalysts for water electrolysis by improving stability and activity.
Doping atomic carbon into Fe2O3 ultrathin nanosheets
Constructing Fe oh III−O−Fe oh III synergistic centers
Measuring operando spectroscopic data and conducting density-functional theory calculations.
Achieved an overpotential of 227 mV for 500 mA cm−2 with 4500-hour durability.
C-Fe2O3 UNSs delivered a cell voltage of 1.72 V at 1.5 A cm−2 over 2800 hours.
Observed a degradation rate of 3.05 mV kh−1 at 3 A cm−2.

Abstract

ABSTRACT The sluggish kinetics of alkaline oxygen evolution reaction (OER), together with the highly polarizing conditions at industrial‐level ampere‐scale current densities, which cause catalyst instability, motivate the search for new approaches to break the challenging activity‐stability trade‐off. Herein, we demonstrate that atomic carbon doping into the octahedral voids of Fe 2 O 3 ultrathin nanosheets (C‐Fe 2 O 3 UNSs) with constructed Fe oh III– O–Fe oh III synergistic centers can modify the coverage of * OH intermediates and allow direct * O– * O radical coupling. This enables both structural and catalytic stabilization, as confirmed by operando spectroscopic measurements and density‐functional theory calculations, with an overpotential of 227 mV to achieve 500 mA cm −2 along with 4500‐h durability. When applying C‐Fe 2 O 3 UNSs in an anion exchange membrane water electrolyzer, it delivers a cell voltage of 1.72 V at 1.5 A cm −2 while operating for 2800 h from 1 to 5 A cm −2 , with a degradation rate of 3.05 mV kh −1 at 3 A cm −2 .

Mark Helpful

Bookmark

Relay