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Atomic-level Ru-Ir mixing in rutile-type (RuIr)O2 for efficient and durable oxygen evolution catalysis

Yeji Park, Ho Yeon Jang, Tae Kyung Lee, Taekyung Kim, Doyeop Kim, Dong-Jin Kim, Hionsuck Baik, Jinwon Choi, Taehyun Kwon, Sung Jong Yoo, Seoin Back, Kwangyeol Lee

2025Nature Communications92 citationsDOIOpen Access PDF

Abstract

Abstract The success of proton exchange membrane water electrolysis (PEMWE) depends on active and robust electrocatalysts to facilitate oxygen evolution reaction (OER). Heteroatom-doped-RuO x has emerged as a promising electrocatalysts because heteroatoms suppress lattice oxygen participation in the OER, thereby preventing the destabilization of surface Ru and catalyst degradation. However, identifying suitable heteroatoms and achieving their atomic-scale coupling with Ru atoms are nontrivial tasks. Herein, to steer the reaction pathway away from the involvement of lattice oxygen, we integrate OER-active Ir atoms into the RuO 2 matrix, which maximizes the synergy between stable Ru and active Ir centers, by leveraging the changeable growth behavior of Ru/Ir atoms on lattice parameter-modulated templates. In PEMWE, the resulting (RuIr)O 2 /C electrocatalysts demonstrate notable current density of 4.96 A cm −2 and mass activity of 19.84 A mg Ru+Ir −1 at 2.0 V. In situ spectroscopic analysis and computational calculations highlight the importance of the synergistic coexistence of Ru/Ir-dual-OER-active sites for mitigating Ru dissolution via the optimization of the binding energy with oxygen intermediates and stabilization of Ru sites.

Topics & Concepts

Oxygen evolutionHeteroatomCatalysisDissolutionChemistryRutileOxygenWater splittingChemical physicsInorganic chemistryMaterials sciencePhysical chemistryElectrochemistryPhotocatalysisOrganic chemistryBiochemistryElectrodeRing (chemistry)Electrocatalysts for Energy ConversionAdvanced battery technologies researchFuel Cells and Related Materials