Alloy as advanced catalysts for electrocatalysis: From materials design to applications

With the deep integration of electrochemical research with energy, environment, catalysis, and other fields, more and more new electrochemical catalytic reactions have entered our research field. Alloy catalysts have recently emerged as a new type of nanomaterial due to the rapid development of kinetic controlled synthesis technology. These materials offer several advantages over monometallic catalysts, including larger element combinations, complex geometries, bifunctional sites, and reduced use of precious metals. This paper provides a review of alloy electrocatalysts that are designed and prepared specifically for electrocatalytic applications. The use of alloy materials in electrocatalyst design is also discussed, highlighting their widespread application in this field. First, various synthesis methods and synthesis mechanisms are systematically summarized. Following that, by correlating the properties of materials with the structure, relevant strategies toward advanced alloy electrocatalysts including composition regulation, size, morphology, surface engineering, defect engineering, interface engineering and strain engineering are classified. In addition, the important electrocatalytic applications and mechanisms of alloy electrocatalysts are described and summarized. Finally, the current challenges and prospects regarding the development of alloy nanomaterials are proposed. This review serves as a springboard from a fundamental understanding of alloy structural dynamics to design and various applications of electrocatalysts, particularly in energy and environmental sustainability. Alloy catalysts exhibit remarkable electrocatalytic performance due to optimized electronic structure, atomic system synthesis conformation and synergistic effects. In this minireview, we provided an overview of recently reported design strategies and applications of alloy catalysts for electrocatalytic related energy technologies, and further outlines the underlying mechanisms behind the enhanced catalytic performance of alloy electrocatalysts. [Display omitted]