Issue 11, 2023

Establishing a unified paradigm of microwave absorption inspired by the merging of traditional microwave absorbing materials and metamaterials

Abstract

The merging of traditional microwave absorbing materials with metamaterials holds significant potential for enhancing microwave absorber performance. To unlock this potential, a unified paradigm is urgently required. We have successfully established such a paradigm, focusing on regulating effective electromagnetic parameters and interfacial forms across microscopic, mesoscopic, and macroscopic scales. Building upon this foundation, we introduce an active co-design methodology for jointly optimizing full-scale structures and the concept of “full-scale microwave absorbers” (FSMAs). Under this guidance, performance improvements can be achieved efficiently, leading to crucial breakthroughs. For demonstration, we present a case study designing ultra-thin miniaturized FSMAs capable of ultra-broadband and low-frequency absorption. Simulation results show absorptivity exceeding 90% in the 2–28 GHz range, with absorptivity surpassing 85% and 74% in the 1.5–2 GHz and 1–1.5 GHz ranges, respectively. Additionally, the total thickness and macro period are only 5 mm, roughly equivalent to 0.033 wavelengths of the lowest operating frequency. Most importantly, we have broken the Rozanov limit, with experimental results further validating this design. This work significantly enhances our understanding of microwave absorption and offers a shortcut for pursuing improved performances and breakthroughs.

Graphical abstract: Establishing a unified paradigm of microwave absorption inspired by the merging of traditional microwave absorbing materials and metamaterials

Supplementary files

Article information

Article type
Communication
Submitted
28 Aug 2023
Accepted
13 Sep 2023
First published
14 Sep 2023

Mater. Horiz., 2023,10, 5202-5213

Establishing a unified paradigm of microwave absorption inspired by the merging of traditional microwave absorbing materials and metamaterials

M. Guo, X. Wang, H. Zhuang, Y. Dai, W. Li, X. Wei, D. Tang, B. Zhang, P. Chen and Y. Yang, Mater. Horiz., 2023, 10, 5202 DOI: 10.1039/D3MH01368E

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