Magnetic Pinning and Multi-scale Polarization Enhance Microwave Absorption of Vacancy-Rich CoFe2O4/Lignin-Derived Carbon Nanofiber Composites

Jixing Bai , Huiyan Zhang , Shenghao Yue , Ke Pei , Lei Wang , Lu-Yang Li , Qi Cao , Miao Jiang , Xiangzhou Yuan , Renchao Che

Advanced Fiber Materials ›› : 1 -13.

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Advanced Fiber Materials ›› :1 -13. DOI: 10.1007/s42765-026-00695-1
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Magnetic Pinning and Multi-scale Polarization Enhance Microwave Absorption of Vacancy-Rich CoFe2O4/Lignin-Derived Carbon Nanofiber Composites
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Abstract

The development of cost-effective and high-performance carbon-based electromagnetic wave (EMW) absorbent has attracted much attention, while achieving complete impedance matching of the material with tunable magnetic and dielectric properties remains a challenge. In this study, vacancy-rich CoFe2O4/lignin-derived N-doped carbon nanofiber composites (CFO@LCF) are obtained as a novel EMW absorption material, in which the synergy of magnetic pinning and multi-scale polarization is achieved by cascade effects originated from the size modulation of encapsulated magnetic CoFe2O4 particles, and the defects in both CoFe2O4 and lignin-derived carbon to enhance the EMW dissipation. In addition, the conduction loss is promoted at the same time by the three-dimensional (3D) interconnected conductive carbon nanofiber network, and meanwhile, the magnetic loss facilitated by strong magnetic coupling and pinning effect occurs at the particles. Specifically, the optimal CFO@LCF sample shows superior EMW absorption performance with a minimum reflection loss of − 49.25 dB at the matching thickness of 2.08 mm, and an effective absorption bandwidth of 6.54 GHz covering the whole Ku band. The superior performance confirms its application potential, and also suggests an innovative biomass valorization pathway for the development of next-generation carbon-based EMW absorbent.

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Keywords

Microwave absorption / Magnetic pinning / Multi-physics simulation / Biomass valorization / Lignin-derived carbon

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Jixing Bai, Huiyan Zhang, Shenghao Yue, Ke Pei, Lei Wang, Lu-Yang Li, Qi Cao, Miao Jiang, Xiangzhou Yuan, Renchao Che. Magnetic Pinning and Multi-scale Polarization Enhance Microwave Absorption of Vacancy-Rich CoFe2O4/Lignin-Derived Carbon Nanofiber Composites. Advanced Fiber Materials 1-13 DOI:10.1007/s42765-026-00695-1

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Funding

Key Technologies Research and Development Program(2022YFE0210500)

National Natural Science Foundation of China(52576196)

Aeronautical Science Foundation of China(2022Z056069001)

National Key Laboratory of Science and Technology on Materials under Shock and Impact(6142902230104)

China-Pakistan Belt and Road Joint Laboratory on Smart Disaster Prevention of Major Infrastructures(2024CPBRJL-03)

RIGHTS & PERMISSIONS

Donghua University, Shanghai, China

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