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Advances in Selenium‐Based Materials for Supercapacitors: Chemistry, Interaction Mechanisms, and Practical Applications

Murugan Madhubalan, S. Sathish, Minda Mahivardhan, T. Prabhakaran, Kannan Karthika Abimanyu, Ramesh Kumar, Jong‐Hyun Seo, Binxi Gu, Subbaiah Muthu Prabhu, Byong‐Hun Jeon

2025Small Structures6 citationsDOIOpen Access PDF

Abstract

High‐performance supercapacitors require electrode materials that can simultaneously deliver elevated energy storage capacity, rapid power output, and long‐term cycling stability. Compared to sulfur analogs, selenium (Se)‐based materials have shown great promise because of their favorable redox activity, enhanced polarizability, and superior electrical conductivity. Herein, recent developments in Co–Se, Ni–Se, sulfoselenides (S–O–Se), and other Se‐based electrode materials are critically reviewed, with emphasis on their synthesis techniques, structural advantages, and electrochemical performance in relation to charge storage mechanisms. Comparative analysis reveals that their capacitance and durability are significantly enhanced by morphological control, heterostructure engineering, and synergistic effects with conductive substrates. The incorporation of Se into materials and their charge storage mechanisms is discussed using density functional theory analysis and artificial intelligence/machine learning approaches. This review highlights the growing contribution of Se‐based electrodes to supercapacitor technology by critically examining their development from basic binary selenides to intricate hybrid systems. Furthermore, the influence of Se metal centers and carbon frameworks in enhancing mechanical stability, active site accessibility, and ion transport is meticulously investigated. To close the gap toward practical next‐generation energy storage devices, the advantages and limitations of Se and its composite systems are evaluated, and prospects for advancing Se‐based electrodes are carefully outlined.

Topics & Concepts

SupercapacitorNanotechnologyEnergy storageMaterials scienceElectrochemical energy storageCapacitanceElectrodeDurabilityBattery (electricity)ElectrochemistryCarbon nanotubeGrapheneComposite numberPower densityCarbon fibersElectrical conductorEnergy densityEngineering physicsCharacterization (materials science)Charge (physics)Supercapacitor Materials and FabricationMXene and MAX Phase MaterialsAdvancements in Battery Materials