Graphene-Skinned Fiber with Fine-Tunable Electrical Resistance via Radical and Substrate Engineering for Electromagnetic-Thermal Fabric

Jie Liang; Zhaochen Li; Fang Ye; Yuchen Cao; Yi An; Xiaomeng Fan; Qiang Song

doi:10.1007/s40820-026-02117-8

Graphene-Skinned Fiber with Fine-Tunable Electrical Resistance via Radical and Substrate Engineering for Electromagnetic-Thermal Fabric

Jie Liang
, Zhaochen Li
, Fang Ye
, Yuchen Cao
, Yi An
, Xiaomeng Fan
, Qiang Song

材料学院

Northwestern Polytechnical University Xian

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

The composition of C₁/C₂/C₆ radicals is strategically regulated by temperature, dictating the growth of either defective or highly textured graphene microstructures. A synergistic strategy involving radical manipulation and substrate effect via methanol- chemical vapor deposition enables precise control of graphene microstructure, allowing fine tuning of sheet resistance from 26 to 150 Ω sq⁻¹. Laser-patterned band-pass frequency selective surface and a sandwich structure synergistically achieve excellent broadband wave transmission (7.29 GHz) and effective Joule heating (72 °C).

源语言	英语
文章编号	263
期刊	Nano-Micro Letters
卷	18
期	1
DOI	https://doi.org/10.1007/s40820-026-02117-8
出版状态	已出版 - 12月 2026

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abstract = "The composition of C1/C2/C6 radicals is strategically regulated by temperature, dictating the growth of either defective or highly textured graphene microstructures. A synergistic strategy involving radical manipulation and substrate effect via methanol- chemical vapor deposition enables precise control of graphene microstructure, allowing fine tuning of sheet resistance from 26 to 150 Ω sq−1. Laser-patterned band-pass frequency selective surface and a sandwich structure synergistically achieve excellent broadband wave transmission (7.29 GHz) and effective Joule heating (72 °C).",

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AU - Liang, Jie

AU - Li, Zhaochen

AU - Ye, Fang

AU - Cao, Yuchen

AU - An, Yi

AU - Fan, Xiaomeng

AU - Song, Qiang

N1 - Publisher Copyright: © The Author(s) 2026.

PY - 2026/12

Y1 - 2026/12

N2 - The composition of C1/C2/C6 radicals is strategically regulated by temperature, dictating the growth of either defective or highly textured graphene microstructures. A synergistic strategy involving radical manipulation and substrate effect via methanol- chemical vapor deposition enables precise control of graphene microstructure, allowing fine tuning of sheet resistance from 26 to 150 Ω sq−1. Laser-patterned band-pass frequency selective surface and a sandwich structure synergistically achieve excellent broadband wave transmission (7.29 GHz) and effective Joule heating (72 °C).

AB - The composition of C1/C2/C6 radicals is strategically regulated by temperature, dictating the growth of either defective or highly textured graphene microstructures. A synergistic strategy involving radical manipulation and substrate effect via methanol- chemical vapor deposition enables precise control of graphene microstructure, allowing fine tuning of sheet resistance from 26 to 150 Ω sq−1. Laser-patterned band-pass frequency selective surface and a sandwich structure synergistically achieve excellent broadband wave transmission (7.29 GHz) and effective Joule heating (72 °C).

KW - Electromagnetic wave

KW - Fiber

KW - Graphene

KW - Joule heating

KW - Radical manipulation

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VL - 18

JO - Nano-Micro Letters

JF - Nano-Micro Letters

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ER -

Graphene-Skinned Fiber with Fine-Tunable Electrical Resistance via Radical and Substrate Engineering for Electromagnetic-Thermal Fabric

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