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Entropy‐Driven Morphology Regulation of MAX Phase Solid Solutions with Enhanced Microwave Absorption and Thermal Insulation Performance

Wei Luo, Xu Jiang, Yi Liu, Xiaoyan Yuan, Jinghao Huo, Peitong Li, Shouwu Guo

2023Small28 citationsDOIOpen Access PDF

Abstract

Abstract Morphology regulation and composition design have proved to be effective strategies for the fabrication of desirable microwave absorbers. However, it is still challenging to precisely control the microstructure and components of MAX phases. Herein, an entropy‐driven approach, a transition from irregular grains (low entropy) to sheet structure (high entropy), is proposed to modulate the morphology of MAX phases. The theoretical calculation indicates that the morphology evolution can be ascribed to the enlarged energy difference between (11_00) and (0001) facets. The enriched structural defects and optimized morphologies yield significant dipolar polarization, interfacial polarization, multiple reflections, and scattering, which all enhance the electromagnetic wave absorption performance of (V 0.25 Ti 0.25 Cr 0.25 Mo 0.25 ) 2 GaC. Specifically, its minimum reflection loss can reach up to −47.12 dB at 12.13 GHz, and the optimal effective absorption bandwidth is 4.56 GHz (2.03 mm). Meanwhile, (V 0.25 Ti 0.25 Cr 0.25 Mo 0.25 ) 2 GaC shows also pronounced thermal insulation properties affording it good reliability in the harsh working environment. This work offers a novel approach to designing and regulating the morphology of the high entropy MAX phase, and also presents an opportunity to elucidate the relationship between entropy and electromagnetic wave absorption performance.

Topics & Concepts

MicrowaveMaterials scienceDipoleFabricationMicrostructureScatteringThermalReflection lossEntropy (arrow of time)OpticsCondensed matter physicsComposite materialThermodynamicsComposite numberPhysicsTelecommunicationsComputer sciencePathologyAlternative medicineQuantum mechanicsMedicineElectromagnetic wave absorption materialsAdvanced Antenna and Metasurface TechnologiesMXene and MAX Phase Materials