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Boosting oxygen evolution reaction by activation of lattice‐oxygen sites in layered Ruddlesden‐Popper oxide

Yinlong Zhu, Hassan A. Tahini, Zhiwei Hu, Yichun Yin, Qian Lin, Hainan Sun, Yijun Zhong, Yubo Chen, Fei-Fei Zhang, Hong‐Ji Lin, Chien‐Te Chen, Wei Zhou, Xiwang Zhang, Sean C. Smith, Zongping Shao, Huanting Wang

2020EcoMat111 citationsDOIOpen Access PDF

Abstract

Abstract Emerging anionic redox chemistry presents new opportunities for enhancing oxygen evolution reaction (OER) activity considering that lattice‐oxygen oxidation mechanism (LOM) could bypass thermodynamic limitation of conventional metal‐ion participation mechanism. Thus, finding an effective method to activate lattice‐oxygen in metal oxides is highly attractive for designing efficient OER electrocatalysts. Here, we discover that the lattice‐oxygen sites in Ruddlesden‐Popper (RP) crystal structure can be activated, leading to a new class of extremely active OER catalyst. As a proof‐of‐concept, the RP Sr 3 (Co 0.8 Fe 0.1 Nb 0.1 ) 2 O 7‐δ (RP‐SCFN) oxide exhibits outstanding OER activity (eg, 334 mV at 10 mA cm −2 in 0.1 M KOH), which is significantly higher than that of the simple SrCo 0.8 Fe 0.1 Nb 0.1 O 3‐δ perovskite and benchmark RuO 2 . Combined density functional theory and X‐ray absorption spectroscopy studies demonstrate that RP‐SCFN follows the LOM under OER condition, and the activated lattice oxygen sites triggered by high covalency of metal‐oxygen bonds are the origin of the high catalytic activity. image

Topics & Concepts

Oxygen evolutionOxideCatalysisOxygenRedoxMetalChemistryCrystal structureMaterials scienceInorganic chemistryPhysical chemistryCrystallographyMetallurgyElectrochemistryElectrodeBiochemistryOrganic chemistryElectrocatalysts for Energy ConversionAdvanced battery technologies researchFuel Cells and Related Materials