Litcius/Paper detail

Cross-scale structural engineering of MOF-derived Co <sub> <i>x</i> </sub> Ni <sub> <i>y</i> </sub> @C nanorods with controllable electromagnetic response behavior for broadband electromagnetic wave absorption

Bo Huang, Fang Ye, Jingwen Deng, Jingchao Wang, Chen Li, Yuchen Cao, Wenjing Zhang, Xiaomeng Fan

2025Journal of Advanced Ceramics7 citationsDOIOpen Access PDF

Abstract

Metal-organic frameworks (MOF) derivatives employed as electromagnetic wave (EMW) absorption materials have gained considerable attention because of their plentiful coordination components and diverse nano-micro structures. However, achieving broadband EMW absorption solely through nano‑microscale structural design remains challenging. Herein, a cross-scale structural engineering strategy is proposed to address this limitation. At the nano-microscale, MOF-derived Co<sub>x</sub>Ni<sub>y</sub>@C nanorods were fabricated via a solvothermal and pyrolysis process. Systematic manipulation of the built-in electric field (BIEF) heterointerfaces achieved through adjusting the Co/Ni atomic ratio significantly promotes electron-directed migration, alters spatial charge distribution, and ultimately enhances the polarization relaxation and magnetic resonance effects, resulting in the superior EMW absorption performance (the effective absorption bandwidth of Co<sub>2</sub>Ni@C is 4.9 GHz at 1.75 mm). Then, the geometric configuration of the electromagnetic metastructures was optimized using CST software. Through cross-scale structural design, the simulated gradient honeycomb structure metamaterial composed of Co<sub>2</sub>Ni@C achieves multi-band compatibility, the EAB reaching 38 GHz (covering 2–40 GHz) with a total thickness of 15 mm. This research elucidates the BIEF loss mechanism of MOF-derived Co<sub>x</sub>Ni<sub>y</sub>@C composites by rationally controlling the Co/Ni atomic ratio and provides novel insights into the structural design of electromagnetic nanomaterials.

Topics & Concepts

Materials scienceNanorodMetamaterialElectromagnetic radiationAbsorption (acoustics)OptoelectronicsStructural materialPolarization (electrochemistry)BroadbandAttenuationElectromagnetic fieldElectromagnetic shieldingElectromagnetic formingHoneycomb structureBandwidth (computing)ElectromagneticsNanotechnologyComposite materialMaterial DesignOpticsDielectricHeterojunctionNanomaterialsElectromagnetic wave absorption materialsMetamaterials and Metasurfaces ApplicationsMagnetic Properties and Synthesis of Ferrites