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Integration of Heterogeneous Interfaces and Multi‐Dimensional Encapsulation Structure in Fe<sub>2</sub>N@CNTs Enabling Highly Efficient Thermal Management and Microwave Absorption

Jian Wang, Zeqing Miao, Kesheng Gao, Zhiqiang Li, Xiaoning Zhang, Chao Yang, Safdar Iqbal, Gaoming Xiang, Anguo Cui, Linhua Liu, Changlong Sun, Hongjing Wu, Jia‐Yue Yang

2024Advanced Functional Materials57 citationsDOI

Abstract

Abstract The opposing effects of interface effect on phonon heat conduction and microwave absorption hinder the integration of thermal conduction with microwave absorption. Reconciling this contradiction by rationally optimizing the material structure remains a challenge. Herein, Fe 2 N@CNTs with heterogeneous interfaces and multi‐dimensional encapsulated structures are fabricated through in situ chemical vapor deposition (CVD) to realize excellent thermal conductivity and microwave absorption. When the mass fraction of active material is 40 wt.%, the thermal conductivity ( λ // ) of Fe 2 N@CNTs composite films is 6.69 W m −1 K −1 . The minimum reflection loss (RL min ) is up to −54.55 dB at a thickness of 3.43 mm, and the effective absorption bandwidth (EAB) is 5.52 GHz at 1.82 mm. The well‐designed Fe 2 N@CNTs is an ideal model for gaining insight into electron transportation and phonon multi‐dimensional heat transport. Heterogeneous interface improves the dielectric loss and facilitates microwave and phonon absorption and conversion. The multi‐dimensional encapsulation structure increases the electron transport path and phonon heat transport paths making axial and radial co‐transfer possible. The multi‐dimensional encapsulation structure demonstrates extremely high microwave absorption and thermal management capabilities, which open up new possibilities for multifunctional applications in host materials with internal hollows.

Topics & Concepts

Materials scienceEncapsulation (networking)MicrowaveThermalCarbon nanotubeNanotechnologyChemical engineeringThermodynamicsPhysicsEngineeringComputer scienceComputer networkQuantum mechanicsElectromagnetic wave absorption materialsDielectric materials and actuatorsFlame retardant materials and properties