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In Situ TEM Reveals the Hard Carbon Sodium Storage Mechanism and Discovers the Sodium Carbide

Huimin Cao, Yizhao Zhao, Zhiyi Huang, Xingxiang Ji, Shoujuan Wang, Wanqi Duan, Yuebin Xi, Yuanwei Sun, Fangong Kong, Yu Liu, Huan Wang

2026Advanced Energy Materials10 citationsDOI

Abstract

ABSTRACT Hard carbon anodes for sodium‐ion batteries rely on Na + insertion into graphite‐like layers below 0.1 V, where closed‐pore structures are critical for high energy density. However, controlling hard carbon microstructures remains challenging. Here, the industrial lignin precursor was simply pre‐pyrolyzed and carbonized to synthesize high‐performance hard carbon with curved graphite‐like layers forming topological cavities. Through GITT and in situ TEM, we visualized Na + (de)intercalation and demonstrated that closed pores (∼1 nm) enhance sodium storage. Even the FFT transform revealed the appearance of a new material lattice (C 32 Na). This work provides insights for tuning hard carbon microstructures and biomass bulk processing and value‐added utilization.

Topics & Concepts

Materials scienceMicrostructureCarbon fibersCarbonizationIn situChemical engineeringSodiumCarbideAnodeBall millWork (physics)Lattice (music)NanotechnologyReinforced carbon–carbonLigninEnergy storageAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesFiber-reinforced polymer composites