International Journal of Extreme Manufacturing (Jan 2023)

A direct laser-synthesized magnetic metamaterial for low-frequency wideband passive microwave absorption

  • Yihe Huang,
  • Yize Li,
  • Kewen Pan,
  • Yixian Fang,
  • Kai Chio Chan,
  • Xiaoyu Xiao,
  • Chao Wei,
  • Kostya S Novoselov,
  • John Gallop,
  • Ling Hao,
  • Zhu Liu,
  • Zhirun Hu,
  • Lin Li

DOI
https://doi.org/10.1088/2631-7990/acdb0c
Journal volume & issue
Vol. 5, no. 3
p. 035503

Abstract

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Microwave absorption in radar stealth technology is faced with challenges in terms of its effectiveness in low-frequency regions. Herein, we report a new laser-based method for producing an ultrawideband metamaterial-based microwave absorber with a highly uniform sheet resistance and negative magnetic permeability at resonant frequencies, which results in a wide bandwidth in the L- to S-band. Control of the electrical sheet resistance uniformity has been achieved with less than 5% deviation at 400 Ω sq ^−1 and 6% deviation at 120 Ω sq ^−1 , resulting in a microwave absorption coefficient between 97.2% and 97.7% within a 1.56–18.3 GHz bandwidth for incident angles of 0°–40°, and there is no need for providing energy or an electrical power source during the operation. Porous N- and S-doped turbostratic graphene 2D patterns with embedded magnetic nanoparticles were produced simultaneously on a polyethylene terephthalate substrate via laser direct writing. The proposed low-frequency, wideband, wide-incident-angle, and high-electromagnetic-absorption microwave absorber can potentially be used in aviation, electromagnetic interference (EMI) suppression, and 5G applications.

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