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Symmetry‐Engineered Carbon Scaffold for Interface‐First Sodium‐Sulfur Batteries

Yue Wang, Nan Zhao, Haobin Song, Yifan Li, Yangfeng Cui, Dongsheng Li, Hui Ying Yang

2025Advanced Materials7 citationsDOI

Abstract

Abstract Room‐temperature sodium–sulfur (RT Na─S) batteries offer high theoretical energy density (1274 Wh kg −1 ) and low‐cost, abundant materials, making them promising for large‐scale energy storage. However, commercialization is hindered by multiple challenges: polysulfide shuttling and sluggish kinetics at the cathode, coupled with dendrite growth and interfacial failure at the anode. Here, an oxygen‐doped carbon fiber (OCF) framework is designed and employed as a bifunctional host within a symmetric all‐carbon‐fiber cell architecture to simultaneously address these issues. The 3D porous OCF framework chemically anchors polysulfides, catalyzes their redox reactions, and guides uniform sodium nucleation/deposition. This synergy suppresses polysulfide shuttling and dendrite growth. Performance tests demonstrate an extremely low Na nucleation overpotential (27 mV at 1 mA cm −2 ) and stable, dendrite‐free cycling exceeding 3600 h. In full Na─S cells, this design delivers a specific capacity of 753 mAh g −1 after 200 cycles at 0.2 C, retains ≈85% capacity after 2000 cycles at 0.5 C, and exhibits excellent rate performance (5 C). Mechanistic studies reveal OCF enhances Na⁺ transport and interfacial kinetic stability. This work presents a generalizable, interface‐first design paradigm for safe, long‐lasting, low‐cost Na─S batteries free from shuttling and dendrites.

Topics & Concepts

OverpotentialPolysulfideMaterials scienceNucleationBifunctionalNanotechnologyEnergy storageDendrite (mathematics)Chemical engineeringCarbon nanofiberCarbon fibersAnodeRedoxPorosityKineticsNanofiberScaffoldElectrodeSiliconFiberAdvanced Battery Materials and TechnologiesThermal Expansion and Ionic ConductivityAdvancements in Battery Materials
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