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Carbon engineering for sodium batteries: multi-role architectures bridging material design and hybrid system innovation

Qianxiong Wen, Chuang‐Chuang Li, Qinghang Chen, Pandeng Zhao, Chun Wu, Xingqiao Wu, Shulei Chou

2025Chemical Society Reviews28 citationsDOI

Abstract

storage for energy-oriented applications and defect-guided Na deposition for power-oriented needs. This system integrates three adaptive operation modes: standard, boost, and survival, enabling scenario-specific optimization for applications ranging from consumer electronics to grid storage and extreme environments. Finally, we identify critical challenges in carbon engineering, such as dynamic interface evolution during mode-switching and potential-driven phase transitions in hybrid systems. By bridging multi-scale carbon design with hybrid battery electrochemistry, this review provides a roadmap for developing Na batteries with broad application compatibility by carbon engineering, addressing both fundamental and technological challenges in sustainable energy storage.

Topics & Concepts

NanotechnologyBattery (electricity)Energy storageMaterials scienceCompatibility (geochemistry)Hybrid systemBridging (networking)Computer scienceElectronicsCarbon fibersElectrochemistrySodium-ion batteryHybrid materialSustainable energyComputer data storageElectrochemical energy storageMaterial DesignRangingSupercapacitorProcess engineeringMaterial selectionGridSystems designAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesInorganic Chemistry and Materials
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