Litcius/Paper detail

Spin State Modulation via Magnetic Fields in Fe Single Atom Catalysts for High-Performance Aqueous Zinc–Sulfur Batteries

Penghao Dai, Jian Lang, Weiyuan Huang, Lu‐Fang Ma, Xueru Zhao, Xiaojing Lin, Qiang Li, Hongpeng Li, Hongpeng Li, Tongchao Liu, Khalil Amine, Hongsen Li, Hongsen Li

2025ACS Nano20 citationsDOI

Abstract

Aqueous zinc–sulfur battery has garnered significant attention as a high-energy, low-cost, and safe energy storage system. However, the multielectron transfer kinetics of sulfur cathodes are relatively slow, presenting challenges such as limited sulfur utilization and lower discharge voltage, which significantly hinder their practical applications. In this study, we explored a comprehensive design approach for high-performance, long-cycle aqueous zinc–sulfur batteries. The simultaneous introduction of ZnI 2 and Fe single atoms (Fe-SAs) as catalytically active agents decouples the redox reactions, effectively facilitating ZnS oxidation and S reduction separately. The application of an external magnetic field regulates the spin state of Fe-SAs, further enhancing their catalytic activity and electron transfer capability. Electrochemical tests demonstrate that the S@Fe-NC HS/ZnI 2 cathode assembled under a magnetic field exhibits excellent rate performance, achieving an impressive specific capacity of 1399 mAh g –1 at a high current density of 5 A g –1 and good cycling stability over 300 cycles, representing the highest reported high-current discharge capacity to date. This study provides a comprehensive design framework for optimizing zinc–sulfur (Zn–S) battery performance and elucidates the influence of magnetic field-induced spin state modulation on catalytic behavior.

Topics & Concepts

SulfurElectrochemistryAqueous solutionCatalysisBattery (electricity)CathodeZincElectron transferRedoxMaterials scienceEnergy storageElectrodeChemistryChemical engineeringInorganic chemistryPhotochemistryThermodynamicsPhysical chemistryMetallurgyPhysicsOrganic chemistryEngineeringPower (physics)Advanced battery technologies researchAdvanced Battery Materials and TechnologiesPerovskite Materials and Applications