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Multilayered gradient Ti2AlC0.5N0.5 prepared by crystal/amorphous C diffusion for efficient electromagnetic absorption and thermal shielding

Cheng Xie, Lei Xu, Zhigang Shen, Junyu Lu, Yongfen Sun, Zhaohui Han, Yuchen Feng, Yanzhi Liu

2025Nature Communications9 citationsDOIOpen Access PDF

Abstract

The unique advantages of surface/interface engineering are pivotal in advancing the design and development of high-performance electromagnetic wave (EMW) absorption materials. We present a universal microwave molten salt carbon (C) diffusion control strategy based on surface/interface engineering. This method leverages microwaves to promote the amorphous transformation and rapid diffusion of C on the carbon fiber surface, allowing for the rapid and controlled formation of three-dimensional multilayered gradient core-shell structures, primarily consisting of Ti2AlC0.5N0.5 MAX. This unique structure with cavities contributes to the incident and multiple EMW losses. TACN-1 exhibited an efficient reflection loss of −83.4 dB at a thickness of just 1.9 mm and effectively isolates internal radiant heat, making it a promising material for stealth applications. This study not only advances the application of diffusion-controlled surface/interface engineering but also introduces a universal approach for modulating multilayered gradient structures in MAX phase ceramics. Surface/interface engineering promotes the development of electromagnetic wave absorbers. Here, the authors present a unique three-dimensional multilayered gradient core-shell structured MAX phase ceramic and report its absorption mechanism.

Topics & Concepts

Materials scienceMicrowaveElectromagnetic shieldingAbsorption (acoustics)DiffusionReflection (computer programming)Temperature gradientElectromagnetic radiationMicrowave heatingThermalAmorphous solidReflection lossPhase (matter)OptoelectronicsCarbon fibersRadiative transferElectromagneticsThin layersOpticsComposite materialOptical fiberThermal radiationFiberTransformation (genetics)Carbon nanotubeNanotechnologyContinuous waveWave propagationPermittivityMXene and MAX Phase MaterialsIntermetallics and Advanced Alloy PropertiesAdvanced ceramic materials synthesis
Multilayered gradient Ti2AlC0.5N0.5 prepared by crystal/amorphous C diffusion for efficient electromagnetic absorption and thermal shielding | Litcius