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Janus electronic state of supported iridium nanoclusters for sustainable alkaline water electrolysis.


ABSTRACT: Metal-support electronic interactions play crucial roles in triggering the hydrogen spillover (HSo) to boost hydrogen evolution reaction (HER). It requires the supported metal of electron-rich state to facilitate the proton adsorption/spillover. However, this electron-rich metal state contradicts the traditional metal→support electron transfer protocol and is not compatible with the electron-donating oxygen evolution reaction (OER), especially in proton-poor alkaline conditions. Here we profile an Ir/NiPS3 support structure to study the Ir electronic states and performances in HSo/OER-integrated alkaline water electrolysis. The supported Ir is evidenced with Janus electron-rich and electron-poor states at the tip and interface regions to respectively facilitate the HSo and OER processes. Resultantly, the water electrolysis (WE) is efficiently implemented with 1.51 V at 10 mA cm-2 for 1000 h in 1 M KOH and 1.44 V in urea-KOH electrolyte. This research clarifies the Janus electronic state as fundamental in rationalizing efficient metal-support WE catalysts.

SUBMITTER: Liu Y 

PROVIDER: S-EPMC10987502 | biostudies-literature | 2024 Apr

REPOSITORIES: biostudies-literature

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Janus electronic state of supported iridium nanoclusters for sustainable alkaline water electrolysis.

Liu Yaoda Y   Li Lei L   Wang Li L   Li Na N   Zhao Xiaoxu X   Chen Ya Y   Sakthivel Thangavel T   Dai Zhengfei Z  

Nature communications 20240402 1


Metal-support electronic interactions play crucial roles in triggering the hydrogen spillover (HSo) to boost hydrogen evolution reaction (HER). It requires the supported metal of electron-rich state to facilitate the proton adsorption/spillover. However, this electron-rich metal state contradicts the traditional metal→support electron transfer protocol and is not compatible with the electron-donating oxygen evolution reaction (OER), especially in proton-poor alkaline conditions. Here we profile  ...[more]

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