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Mechanism‐Driven Modification of Transition Metal Selenides as Sodium‐Ion Battery Anodes: A Review

Linlin Tai, Shiyi Zeng, Gaigai Duan, Yong Huang, Weijun Li, Xiaoshuai Han, Chunmei Zhang, Shuijian He, Shaohua Jiang

2025Advanced Energy Materials8 citationsDOI

Abstract

ABSTRACT In the face of increasingly severe energy and environmental challenges, the development of high‐performance, sustainable sodium‐ion battery (SIB) anode materials has become a research priority in the field of energy storage. Transition metal selenides (TMSes) have demonstrated great potential as SIB anodes due to their high theoretical capacity and unique physical and chemical properties. However, their practical application remains limited by multiple challenges, including reaction kinetics hysteresis, structural instability, and interfacial side reactions. This review begins with the sodium storage reaction mechanism, systematically addressing key scientific issues in multiple stages of TMSes, including intercalation, conversion, and alloying. It proposes a mechanism‐driven multi‐scale modification strategy. This strategy encompasses innovative approaches such as interlayer engineering, defect control, heterostructure construction, carbon‐based composites, electrolyte optimization, and interface modification. These strategies significantly enhance the initial coulombic efficiency, rate performance, and long‐term cycling stability of TMSes anodes, achieving synergistic optimization from atomic‐level electronic structure regulation to macroscopic structural design.

Topics & Concepts

Materials scienceFaraday efficiencyAnodeElectrolyteBattery (electricity)NanotechnologyEnergy storageHeterojunctionSustainable energyTransition metalInterface (matter)Chemical stabilityKey (lock)MetalChemical engineeringElectronicsEngineering physicsEnergy transformationStructural stabilityField (mathematics)Electronic structureChemical energyElectrochemistryPotassium-ion batteryAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesThermal Expansion and Ionic Conductivity
Mechanism‐Driven Modification of Transition Metal Selenides as Sodium‐Ion Battery Anodes: A Review | Litcius