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Emerging Exsolution Materials for Diverse Energy Applications: Design, Mechanism, and Future Prospects

Hyeongwon Jeong, Yo Han Kim, Bo‐Ram Won, Hyejin Jeon, Chan‐ho Park, Jae‐ha Myung

2023Chemistry of Materials39 citationsDOI

Abstract

Nanostructured catalytic materials are considered to be a favorable design concept for various energy conversion and storage systems. Nanosized metal catalysts supported on oxide scaffolds have been adopted in numerous fields, including fuel cells, gas sensors, and chemical reforming devices. Nevertheless, nanometal catalysts often suffer from durability issues. Although surface-decorated nanometal catalysts can deliver sufficient catalytic activity, some of them still exhibit durability issues in severe operating environments. Recently, nanocatalysts produced by in situ exsolution have been demonstrated to overcome the practical limitations of conventional nanometal catalysts. The exsolution is defined as a process in which a catalytically active dopant in perovskite oxide is exsolved on its surface as highly dispersed nanometal catalysts. In particular, exsolution nanocatalysts embedded on perovskite oxides exhibit higher nanoparticle densities and greater resistance to particle agglomeration than conventional nanometal catalysts. This Perspective presents an overview of recent advances in exsolution materials for energy applications including fundamental mechanisms, design strategies for host oxides, and practical applications. The future prospects of these materials and the scope for further optimization are also discussed.

Topics & Concepts

Nanomaterial-based catalystCatalysisMaterials scienceOxideNanotechnologyPerovskite (structure)Characterization (materials science)Rational designDurabilityDopantNanoparticleChemical engineeringDopingChemistryOptoelectronicsComposite materialBiochemistryMetallurgyEngineeringAdvancements in Solid Oxide Fuel CellsElectrocatalysts for Energy ConversionCatalytic Processes in Materials Science
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