Leaf vein micronetwork engineering enhanced energy conversion strategy for C-band ultralight yet tunable microwave absorption

IF 11 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Rare Metals Pub Date : 2025-05-25 DOI:10.1007/s12598-025-03360-5

Chunyan Ding, Chengshuai Shao, Zhen Wang, Zhuoyang Li, Xue Guo, Xiaozhen Ren, Hongchang Pei, Songsong Wu, Qianqian Zhang, Chuncheng Wei, Long Xia, Bo Zhong, Guangwu Wen, Xiaoxiao Huang

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引用次数: 0

Abstract

Lightweight materials with wide absorption capabilities, particularly in the C-band, have remained a challenge thus far. Recent research has indicated that effective absorption networks built by microfiber polarization loss can be a significant factor in increasing the effective absorption bandwidth (EAB). In this study, leaf vein-like carbon (LVC) was synthesized using an in situ blowing strategy. Taking inspiration from photosynthesis energy conversion mechanisms, a leaf veins-like hierarchical structure was created to establish an effective impedance-matching network and generate a high-density polarization region through leaf vein microfibers. This enhanced polarization relaxation effectively broadens the EAB of the LVC. At a low filling ratio of 6.3 wt%, the EAB of the LVC covers 80% of the C-band, as well as 100% of the X-band and Ku-band. Achieving such a wide EAB in the C-band, especially in the multi-band context, relies on impedance matching and optimized polarization relaxation. This work demonstrates the crucial role of leaf vein micronetwork engineering in enhancing the C-band absorption properties of carbon-based materials, thus providing a viable reference for the development of lightweight, broadband, and highly absorptive materials for electromagnetic applications.

Graphical abstract

The in situ blowing strategy was employed to achieve interface engineering in the hierarchically configuration leaf vein-like carbon (LVC) nanosheets, and the LVCs obtained could cover the 100% X-band, the entire Ku-band, and the 80% C-band at ultra-low filling (6.3 wt%).

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叶脉微网络工程增强c波段超轻可调谐微波吸收能量转换策略

到目前为止，具有广泛吸收能力的轻质材料，特别是在c波段，仍然是一个挑战。近年来的研究表明，利用微光纤极化损耗构建有效吸收网络是提高有效吸收带宽的重要因素。本研究采用原位吹制的方法合成了叶脉状碳（LVC）。受光合作用能量转换机制的启发，创建了叶脉状的分层结构，通过叶脉微纤维建立有效的阻抗匹配网络，产生高密度极化区。这种增强的极化弛豫有效地拓宽了LVC的EAB。在低填充率为6.3 wt%时，LVC的EAB覆盖了80%的c波段，100%的x波段和ku波段。在c波段实现如此宽的EAB，特别是在多波段环境下，依赖于阻抗匹配和优化的极化弛豫。这项工作证明了叶脉微网络工程在增强碳基材料c波段吸收性能方面的关键作用，从而为开发轻量化、宽带、高吸收的电磁材料提供了可行的参考。采用原位吹制策略对分层结构的叶脉状碳纳米片进行了界面工程处理，得到的叶脉状碳纳米片在超低填充（6.3 wt%）条件下可以覆盖100%的x波段、整个ku波段和80%的c波段。

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

Rare Metals 工程技术-材料科学：综合

CiteScore

12.10

自引率

12.50%

发文量

2919

审稿时长

2.7 months

期刊介绍： Rare Metals is a monthly peer-reviewed journal published by the Nonferrous Metals Society of China. It serves as a platform for engineers and scientists to communicate and disseminate original research articles in the field of rare metals. The journal focuses on a wide range of topics including metallurgy, processing, and determination of rare metals. Additionally, it showcases the application of rare metals in advanced materials such as superconductors, semiconductors, composites, and ceramics.