Water-Resonator-Based Metasurface: An Ultrabroadband and Near-Unity Absorption

Qinghua Song; Wu Zhang; Pin Chieh Wu; Weiming Zhu; Zhong Xiang Shen; Peter Han Joo Chong; Qing Xuan Liang; Zhen Chuan Yang; Yi Long Hao; Hong Cai; Hai Feng Zhou; Yuandong Gu; Guo Qiang Lo; Din Ping Tsai; Tarik Bourouina; Yamin Leprince-Wang; Ai Qun Liu

doi:10.1002/adom.201601103

Water-Resonator-Based Metasurface: An Ultrabroadband and Near-Unity Absorption

Qinghua Song
, Wu Zhang
, Pin Chieh Wu
, Weiming Zhu
, Zhong Xiang Shen
, Peter Han Joo Chong
, Qing Xuan Liang
, Zhen Chuan Yang
, Yi Long Hao
, Hong Cai
, Hai Feng Zhou
, Yuandong Gu
, Guo Qiang Lo
, Din Ping Tsai
, Tarik Bourouina
, Yamin Leprince-Wang
, Ai Qun Liu

School of Mechanical Engineering

Universite de Marne-la-Valle
Nanyang Technological University
Harvard University
Agency for Science, Technology and Research, Singapore
Auckland University of Technology
Peking University
Academia Sinica - Research Center for Applied Science
Université Paris-Est

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

146 Scopus citations

Abstract

Metasurface absorbing material, which obtains near-unity electromagnetic absorption through subwavelength artificial structure, plays an important role in the area of stealth and shielding technology, biological imaging, etc. However, they usually suffer from narrow bandwidth and only work on planar surfaces. Here, for the first time, this study demonstrates a soft water-resonator-based metasurface, which functions as an active absorbing material across an ultrabroadband range of Ku, K, and Ka bands. Distinct from conventional metallic metasurface, the water-resonator-based metasurface absorbs the microwave by dielectric magnetic resonance and periodic grating effect, which has a perfect absorptivity of ≈99% and an absorption bandwidth (absorptivity higher than 90%) that covers 78.9% of the central frequency. Furthermore, near-unity absorption is maintained when the soft metasurface material is bent into different curvatures, promising high potential applications for antennas in reducing side lobe radiation, eliminating wall reflection in anechoic chambers, antiradar detection, and stealth.

Original language	English
Article number	1601103
Journal	Advanced Optical Materials
Volume	5
Issue number	8
DOIs	https://doi.org/10.1002/adom.201601103
State	Published - 18 Apr 2017

Keywords

absorber
metasurfaces
tunable absorption

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10.1002/adom.201601103

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Song, Q., Zhang, W., Wu, P. C., Zhu, W., Shen, Z. X., Chong, P. H. J., Liang, Q. X., Yang, Z. C., Hao, Y. L., Cai, H., Zhou, H. F., Gu, Y., Lo, G. Q., Tsai, D. P., Bourouina, T., Leprince-Wang, Y., & Liu, A. Q. (2017). Water-Resonator-Based Metasurface: An Ultrabroadband and Near-Unity Absorption. Advanced Optical Materials, 5(8), Article 1601103. https://doi.org/10.1002/adom.201601103

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title = "Water-Resonator-Based Metasurface: An Ultrabroadband and Near-Unity Absorption",

abstract = "Metasurface absorbing material, which obtains near-unity electromagnetic absorption through subwavelength artificial structure, plays an important role in the area of stealth and shielding technology, biological imaging, etc. However, they usually suffer from narrow bandwidth and only work on planar surfaces. Here, for the first time, this study demonstrates a soft water-resonator-based metasurface, which functions as an active absorbing material across an ultrabroadband range of Ku, K, and Ka bands. Distinct from conventional metallic metasurface, the water-resonator-based metasurface absorbs the microwave by dielectric magnetic resonance and periodic grating effect, which has a perfect absorptivity of ≈99\% and an absorption bandwidth (absorptivity higher than 90\%) that covers 78.9\% of the central frequency. Furthermore, near-unity absorption is maintained when the soft metasurface material is bent into different curvatures, promising high potential applications for antennas in reducing side lobe radiation, eliminating wall reflection in anechoic chambers, antiradar detection, and stealth.",

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author = "Qinghua Song and Wu Zhang and Wu, \{Pin Chieh\} and Weiming Zhu and Shen, \{Zhong Xiang\} and Chong, \{Peter Han Joo\} and Liang, \{Qing Xuan\} and Yang, \{Zhen Chuan\} and Hao, \{Yi Long\} and Hong Cai and Zhou, \{Hai Feng\} and Yuandong Gu and Lo, \{Guo Qiang\} and Tsai, \{Din Ping\} and Tarik Bourouina and Yamin Leprince-Wang and Liu, \{Ai Qun\}",

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doi = "10.1002/adom.201601103",

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AU - Song, Qinghua

AU - Zhang, Wu

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AU - Zhu, Weiming

AU - Shen, Zhong Xiang

AU - Chong, Peter Han Joo

AU - Liang, Qing Xuan

AU - Yang, Zhen Chuan

AU - Hao, Yi Long

AU - Cai, Hong

AU - Zhou, Hai Feng

AU - Gu, Yuandong

AU - Lo, Guo Qiang

AU - Tsai, Din Ping

AU - Bourouina, Tarik

AU - Leprince-Wang, Yamin

AU - Liu, Ai Qun

PY - 2017/4/18

Y1 - 2017/4/18

N2 - Metasurface absorbing material, which obtains near-unity electromagnetic absorption through subwavelength artificial structure, plays an important role in the area of stealth and shielding technology, biological imaging, etc. However, they usually suffer from narrow bandwidth and only work on planar surfaces. Here, for the first time, this study demonstrates a soft water-resonator-based metasurface, which functions as an active absorbing material across an ultrabroadband range of Ku, K, and Ka bands. Distinct from conventional metallic metasurface, the water-resonator-based metasurface absorbs the microwave by dielectric magnetic resonance and periodic grating effect, which has a perfect absorptivity of ≈99% and an absorption bandwidth (absorptivity higher than 90%) that covers 78.9% of the central frequency. Furthermore, near-unity absorption is maintained when the soft metasurface material is bent into different curvatures, promising high potential applications for antennas in reducing side lobe radiation, eliminating wall reflection in anechoic chambers, antiradar detection, and stealth.

AB - Metasurface absorbing material, which obtains near-unity electromagnetic absorption through subwavelength artificial structure, plays an important role in the area of stealth and shielding technology, biological imaging, etc. However, they usually suffer from narrow bandwidth and only work on planar surfaces. Here, for the first time, this study demonstrates a soft water-resonator-based metasurface, which functions as an active absorbing material across an ultrabroadband range of Ku, K, and Ka bands. Distinct from conventional metallic metasurface, the water-resonator-based metasurface absorbs the microwave by dielectric magnetic resonance and periodic grating effect, which has a perfect absorptivity of ≈99% and an absorption bandwidth (absorptivity higher than 90%) that covers 78.9% of the central frequency. Furthermore, near-unity absorption is maintained when the soft metasurface material is bent into different curvatures, promising high potential applications for antennas in reducing side lobe radiation, eliminating wall reflection in anechoic chambers, antiradar detection, and stealth.

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KW - metasurfaces

KW - tunable absorption

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DO - 10.1002/adom.201601103

M3 - 文章

AN - SCOPUS:85016024246

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JO - Advanced Optical Materials

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ER -

Water-Resonator-Based Metasurface: An Ultrabroadband and Near-Unity Absorption

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