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Multi‐Dimensional High‐Entropy Materials for Energy Conversion Reactions: Current State and Future Trends

Yilin Dong, Lihua Zhang, Tong Wu, Yinbo Zhan, Bowei Zhou, Fei Wei, Dongliang Zhang, Xia Long

2024ChemSusChem9 citationsDOIOpen Access PDF

Abstract

The high-entropy materials (HEMs), composed of five or more elements, have attracted significant attention in electrocatalysis due to their unique physicochemical properties arising from the existence of multi-elements compositions. Beyond chemical composition, microstructure significantly influences the catalytic performance and even the catalytic mechanism towards energy conversion reactions. Given the rapid proliferation of research on HEMs and the critical roles of microstructure in their catalytic performance, a timely and comprehensive review of recent advancements is imperative. This review meticulously examines the synthesis methods and physicochemical characteristics of HEMs with distinct one-dimensional (1D), two-dimensional (2D), and three-dimensional (3D) morphologies. By highlighting representative examples from the past five years, we elucidate the unique properties of HEMs with 1D, 2D, and 3D microstructures, detailing their intricate influence on electrocatalytic performance, aiming to spur further advancements in this promising research area.

Topics & Concepts

Energy transformationCurrent (fluid)NanotechnologyMaterials scienceEngineering physicsStatistical physicsChemical physicsChemistryThermodynamicsPhysicsHigh Entropy Alloys StudiesMachine Learning in Materials ScienceCatalytic Processes in Materials Science
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