Heterointerface-Engineered SiC@SiO₂@C Nanofibers for Simultaneous Microwave Absorption and Corrosion Resistance.

IF 14.1 1区材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Advanced Science Pub Date : 2025-07-31 DOI:10.1002/advs.202509071

Limeng Song, Feiyue Hu, Yongqiang Chen, Li Guan, Peigen Zhang, Linan Wang, ZhengMing Sun, Yanqiu Zhu, Hailong Wang, Renchao Che, Bingbing Fan, Rui Zhang

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Abstract

To meet the demands of maritime defense and transportation, next-generation microwave absorption (MA) materials must combine efficient attenuation and corrosion resistance (CR). SiC nanofibers, with their moderate dielectric constant and chemical inertness, are ideal multifunctional coating fillers. However, their single-component nature limits microwave attenuation, resulting in low efficiency and narrow bandwidth. Incorporating corrosion-resistant components and employing heterointerface engineering offers a promising strategy to enhance polarization loss and synergistically improve CR. In this study, SiC nanofibers synthesized via chemical vapor deposition are used as precursors; SiO₂ interlayers and nitrogen-doped carbon shells are sequentially introduced to form multilayered core-shell nanofibers. Abundant heterointerfaces and defects effectively regulate impedance matching and introduce multiple loss mechanisms, including conduction, interfacial, and defect-induced dipole polarization. The prepared SiC@SiO₂@C (SSC) nanofibers achieve a minimum reflection loss of -52.40 dB, a maximum effective absorption bandwidth of 7.68 GHz, and a maximum radar cross-section reduction of 38.42 dB m², demonstrating excellent MA properties. Moreover, SSC/polyvinylidene fluoride (PVDF) composite coatings exhibit superior CR performance, with significantly enhanced corrosion potential and reduced current density compared to pure metal and PVDF coatings. This study underscores the synergistic effect of heterointerface engineering in enhancing both MA and CR for harsh environments.

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异质界面工程SiC@SiO2@C纳米纤维的同时微波吸收和耐腐蚀性。

为了满足海上国防和交通运输的需求，下一代微波吸收（MA）材料必须结合高效衰减和耐腐蚀（CR）。SiC纳米纤维具有适中的介电常数和化学惰性，是理想的多功能涂层填料。然而，它们的单组分特性限制了微波衰减，导致效率低、带宽窄。本文以化学气相沉积法合成的SiC纳米纤维为前驱体；将二氧化硅夹层和氮掺杂碳壳依次引入，形成多层核壳纳米纤维。丰富的异质界面和缺陷有效地调节了阻抗匹配，并引入了多种损耗机制，包括传导、界面和缺陷诱导的偶极极化。制备的SiC@SiO2@C （SSC）纳米纤维的反射损耗最小为-52.40 dB，有效吸收带宽最大为7.68 GHz，雷达截面最大减小为38.42 dB m2，具有优异的毫安性能。此外，与纯金属和PVDF涂层相比，SSC/聚偏氟乙烯（PVDF）复合涂层表现出优异的CR性能，具有显著增强的腐蚀电位和降低的电流密度。该研究强调了异质界面工程在提高恶劣环境下的MA和CR方面的协同效应。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advanced Science CHEMISTRY, MULTIDISCIPLINARYNANOSCIENCE &-NANOSCIENCE & NANOTECHNOLOGY

CiteScore

18.90

自引率

2.60%

发文量

1602

审稿时长

1.9 months

期刊介绍： Advanced Science is a prestigious open access journal that focuses on interdisciplinary research in materials science, physics, chemistry, medical and life sciences, and engineering. The journal aims to promote cutting-edge research by employing a rigorous and impartial review process. It is committed to presenting research articles with the highest quality production standards, ensuring maximum accessibility of top scientific findings. With its vibrant and innovative publication platform, Advanced Science seeks to revolutionize the dissemination and organization of scientific knowledge.