1. Domain-limited growth strategy to construct Fe3C@C@CNTs heterogeneous interfaces for multi-functional high-performance lithium-ion storage and microwave absorption.
- Author
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Miao, Zeqing, Li, Dazhi, Zhao, Laibin, Gao, Kesheng, Sun, Wei, Zhao, Wenxin, Yuan, Liying, Zhang, Haihang, Li, Zeyang, Wang, Yan-jie, Li, Zhenjiang, Zhang, Meng, and Sun, Changlong
- Subjects
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ELECTROMAGNETIC wave absorption , *POLARIZATION of electromagnetic waves , *CHEMICAL vapor deposition , *ELECTRIC fields , *MICROWAVES , *CARBON nanotubes , *ELECTRON transport - Abstract
Rational designed cost-effective material is significant in the field of electric energy storage and microwave absorber. In this work, carbon coated Fe 3 C nanoparticles (NPs) encapsulated carbon nanotubes (Fe 3 C@C@CNTs) is delicately constructed through in-situ chemical vapor deposition (CVD) strategy. As a promising anode material for lithium-ion batteries (LIBs), the Fe 3 C@C@CNTs nanocomposite facilitates electron transport with intensive interfacial interaction, making it an ideal prototype to thoroughly understand the mechanisms of interatomic charge transfer mechanism. As a result, this well-designed Fe 3 C@C@CNTs anode exhibits a high reversible capacity of 1027 mAh g−1 after 150 cycles at 0.1 A g−1 and excellent cycling stability with 71 % capacity retention at 519 mAh g−1 after 1000 cycles at 1.0 A g−1. Electrochemical kinetic results confirm that the pseudocapacitance contributions reach up to 90.1 % at 1.0 mV s−1, and the higher pseudocapacitance characteristic is ascribed to the multi-dimensional encapsulated by CNT layer and carbon layer. Meanwhile, depending on the peculiar cavity structure and heterogeneous interfaces effects constructed by multi-dimensional encapsulated structure, the minimum reflection loss (RL min) of Fe 3 C@C@CNTs nanocomposite can reach up to −67.63 dB in effective absorption bandwidth (EAB) of 7.12 GHz with the optimal matching thickness of 2.28 mm, suggesting its extensive potential application as practical alternative absorber. This domain-limited growth strategy opens a new horizon to achieve multi-functional application and beyond for Fe-based nanomaterial. [Display omitted] • Fe 3 C@C@CNTs is prepared by in-situ chemical vapor deposition method. • The multi-dimensional encapsulated structure can maintain electrochemical activity and increase electronic transmission path. • The heterogeneous interfaces can provide abundant active sites for lithium-ion storage and induce significant interfacial polarization for electromagnetic wave attenuation. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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