A pattern design strategy for microwave-absorbing coding metamaterials with tortuosity and connectivity

Ruijiang Fan; Dawei Li; Wenhe Liao; Tingting Liu; Xiangjia Li; Tengteng Tang; Junming Zhao; Tian Jiang

doi:10.1016/j.compositesb.2024.111880

A pattern design strategy for microwave-absorbing coding metamaterials with tortuosity and connectivity

Ruijiang Fan, Dawei Li, Wenhe Liao, Tingting Liu, Xiangjia Li, Tengteng Tang, Junming Zhao, Tian Jiang

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Microwave absorption presents a challenge for the design of metamaterials, which is critical for the stealth and electromagnetic compatibility. To address this, a novel design strategy for patterns is proposed to enhance the wave absorption, which is tortuosity and connectivity. Utilizing the carbon ink composite and genetic algorithm, multi-layer coding metamaterials (MCMs) are designed to satisfy diverse engineering specifications, with reflectivity tests confirming their efficacy. Temperature alternation experiments simulate frequent environmental changes, and the absorptivity of MCMs is compared to evaluate their resilience. This approach ensures the designed MCMs maintain performance and stability under variable thermal conditions, offering a robust solution for advanced applications.

Original language	English (US)
Article number	111880
Journal	Composites Part B: Engineering
Volume	287
DOIs	https://doi.org/10.1016/j.compositesb.2024.111880
State	Published - Dec 2024
Externally published	Yes

Keywords

Broadband microwave absorption
Carbon ink composite
Engineering applications
Multifunctional coding metamaterials
Pattern design strategy

ASJC Scopus subject areas

Ceramics and Composites
Mechanics of Materials
Mechanical Engineering
Industrial and Manufacturing Engineering

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10.1016/j.compositesb.2024.111880

Cite this

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title = "A pattern design strategy for microwave-absorbing coding metamaterials with tortuosity and connectivity",

abstract = "Microwave absorption presents a challenge for the design of metamaterials, which is critical for the stealth and electromagnetic compatibility. To address this, a novel design strategy for patterns is proposed to enhance the wave absorption, which is tortuosity and connectivity. Utilizing the carbon ink composite and genetic algorithm, multi-layer coding metamaterials (MCMs) are designed to satisfy diverse engineering specifications, with reflectivity tests confirming their efficacy. Temperature alternation experiments simulate frequent environmental changes, and the absorptivity of MCMs is compared to evaluate their resilience. This approach ensures the designed MCMs maintain performance and stability under variable thermal conditions, offering a robust solution for advanced applications.",

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AU - Fan, Ruijiang

AU - Li, Dawei

AU - Liao, Wenhe

AU - Liu, Tingting

AU - Li, Xiangjia

AU - Tang, Tengteng

AU - Zhao, Junming

AU - Jiang, Tian

PY - 2024/12

Y1 - 2024/12

N2 - Microwave absorption presents a challenge for the design of metamaterials, which is critical for the stealth and electromagnetic compatibility. To address this, a novel design strategy for patterns is proposed to enhance the wave absorption, which is tortuosity and connectivity. Utilizing the carbon ink composite and genetic algorithm, multi-layer coding metamaterials (MCMs) are designed to satisfy diverse engineering specifications, with reflectivity tests confirming their efficacy. Temperature alternation experiments simulate frequent environmental changes, and the absorptivity of MCMs is compared to evaluate their resilience. This approach ensures the designed MCMs maintain performance and stability under variable thermal conditions, offering a robust solution for advanced applications.

AB - Microwave absorption presents a challenge for the design of metamaterials, which is critical for the stealth and electromagnetic compatibility. To address this, a novel design strategy for patterns is proposed to enhance the wave absorption, which is tortuosity and connectivity. Utilizing the carbon ink composite and genetic algorithm, multi-layer coding metamaterials (MCMs) are designed to satisfy diverse engineering specifications, with reflectivity tests confirming their efficacy. Temperature alternation experiments simulate frequent environmental changes, and the absorptivity of MCMs is compared to evaluate their resilience. This approach ensures the designed MCMs maintain performance and stability under variable thermal conditions, offering a robust solution for advanced applications.

KW - Broadband microwave absorption

KW - Carbon ink composite

KW - Engineering applications

KW - Multifunctional coding metamaterials

KW - Pattern design strategy

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A pattern design strategy for microwave-absorbing coding metamaterials with tortuosity and connectivity

Abstract

Keywords

ASJC Scopus subject areas

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