Download This PaperLocalized Electronic Interaction Dictates Electrolysis Reactivity of Long-Range Palladium Particles
49 Pages Posted: 24 Oct 2024
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Localized Electronic Interaction Dictates Electrolysis Reactivity of Long-Range Palladium Particles
Localized Electronic Interaction Dictates Electrolysis Reactivity of Long-Range Palladium Particles
Abstract
Harnessing the charge transfer between metal and semiconductor supports can radically boost its catalytic activity. At the microscopic level, relative to the single-atom catalyst systems and well-defined models, etc., the details of long-range metal particle-semiconductor interactions remain obscure. This study, through surface oxygenation protocol, confirms two types of metal-support interaction on metal assays of technologically important Pd/C catalysts during H2O2 electrolysis: electron transfer from the Pd particle to the carbon and localized electronic disturbance between Pd/PdO interfaces, thus is inherently an electronic metal-support interaction effect. Remarkably, detailed spectroscopic investigations and theory simulation reveal that interfacial positive palladium governs the reactivity of Pd/PdO in H2O2 electrolysis. Regarding the electron redistribution on palladium particles (50~100 nm), metallic and positively charged Pd moieties enable bifunctional electrolysis. This finding details the quest for catalytically indispensable Pd–O species on carbon and clarifies the prevailing structure-activity relationships of Pd-based catalysts.
Keywords: Long-range Pd particles, H2O2 electrolysis, fuel cell, electronic metal-support interaction, bifunctional working catalysts
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