Extreme diffraction management in phase-corrected gradient metasurface by fourier harmonic component engineering
Beam diffraction management with on-demand efficiency over compact devices is important in various applications, such as communications, spectroscopy, wireless power transfer, and others. Recently, the in-depth study of metasurfaces, such as phase gradient metasurfaces (PGMs) or metagratings (MGs) m...
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sg-ntu-dr.10356-1703072023-09-06T04:27:35Z Extreme diffraction management in phase-corrected gradient metasurface by fourier harmonic component engineering Wang, Yuxiang Yuan, Yueyi Liu, Yi Ding, Xumin Ratni, Badreddine Wu, Qun Burokur, Shah Nawaz Hu, Guangwei Zhang, Kuang School of Electrical and Electronic Engineering Engineering::Electrical and electronic engineering Diffraction Orders Energy Distribution Beam diffraction management with on-demand efficiency over compact devices is important in various applications, such as communications, spectroscopy, wireless power transfer, and others. Recently, the in-depth study of metasurfaces, such as phase gradient metasurfaces (PGMs) or metagratings (MGs) made of discrete elements, has promoted an ultrathin platform to manipulate diffractions. However, most studies only focus on symmetrical diffraction orders or different propagating diffraction orders with equally distributed energy. It is difficult to efficiently excite beams with arbitrary energy distribution by phase-only metasurfaces due to the complex optimization procedure. Here, to address these challenges, Fourier harmonic component engineering is proposed to allocate the energy between multiple diffraction beams. By introducing phase-corrected gradient (PCG) on the metasurface platform, lossless transformation from the incidence to far-field patterns can be obtained. A variety of diffraction situations are considered (symmetric and asymmetric, with equal or arbitrary energy ratio), where the simulated and measured far-field patterns are in excellent agreement with the theoretical predictions and the achieved diffraction efficiency is up to 98.3%. The proposed method paves the way for multichannel wireless communication applications and can be readily extended to other frequency regions. Nanyang Technological University This work was supported by the National Science Foundation of China (No. 62171165), the Natural Science Foundation of Heilongjiang Province (YQ2020F002), and the Start‐up Grant of Nanyang Technological University (#022527‐00001). 2023-09-06T04:27:34Z 2023-09-06T04:27:34Z 2023 Journal Article Wang, Y., Yuan, Y., Liu, Y., Ding, X., Ratni, B., Wu, Q., Burokur, S. N., Hu, G. & Zhang, K. (2023). Extreme diffraction management in phase-corrected gradient metasurface by fourier harmonic component engineering. Laser and Photonics Reviews, 17(7), 2300152-. https://dx.doi.org/10.1002/lpor.202300152 1863-8880 https://hdl.handle.net/10356/170307 10.1002/lpor.202300152 2-s2.0-85159592109 7 17 2300152 en 022527‐00001 Laser and Photonics Reviews © 2023 Wiley-VCH GmbH. All rights reserved. |
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Engineering::Electrical and electronic engineering Diffraction Orders Energy Distribution Wang, Yuxiang Yuan, Yueyi Liu, Yi Ding, Xumin Ratni, Badreddine Wu, Qun Burokur, Shah Nawaz Hu, Guangwei Zhang, Kuang Extreme diffraction management in phase-corrected gradient metasurface by fourier harmonic component engineering |
| description |
Beam diffraction management with on-demand efficiency over compact devices is important in various applications, such as communications, spectroscopy, wireless power transfer, and others. Recently, the in-depth study of metasurfaces, such as phase gradient metasurfaces (PGMs) or metagratings (MGs) made of discrete elements, has promoted an ultrathin platform to manipulate diffractions. However, most studies only focus on symmetrical diffraction orders or different propagating diffraction orders with equally distributed energy. It is difficult to efficiently excite beams with arbitrary energy distribution by phase-only metasurfaces due to the complex optimization procedure. Here, to address these challenges, Fourier harmonic component engineering is proposed to allocate the energy between multiple diffraction beams. By introducing phase-corrected gradient (PCG) on the metasurface platform, lossless transformation from the incidence to far-field patterns can be obtained. A variety of diffraction situations are considered (symmetric and asymmetric, with equal or arbitrary energy ratio), where the simulated and measured far-field patterns are in excellent agreement with the theoretical predictions and the achieved diffraction efficiency is up to 98.3%. The proposed method paves the way for multichannel wireless communication applications and can be readily extended to other frequency regions. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Wang, Yuxiang Yuan, Yueyi Liu, Yi Ding, Xumin Ratni, Badreddine Wu, Qun Burokur, Shah Nawaz Hu, Guangwei Zhang, Kuang |
| format |
Article |
| author |
Wang, Yuxiang Yuan, Yueyi Liu, Yi Ding, Xumin Ratni, Badreddine Wu, Qun Burokur, Shah Nawaz Hu, Guangwei Zhang, Kuang |
| author_sort |
Wang, Yuxiang |
| title |
Extreme diffraction management in phase-corrected gradient metasurface by fourier harmonic component engineering |
| title_short |
Extreme diffraction management in phase-corrected gradient metasurface by fourier harmonic component engineering |
| title_full |
Extreme diffraction management in phase-corrected gradient metasurface by fourier harmonic component engineering |
| title_fullStr |
Extreme diffraction management in phase-corrected gradient metasurface by fourier harmonic component engineering |
| title_full_unstemmed |
Extreme diffraction management in phase-corrected gradient metasurface by fourier harmonic component engineering |
| title_sort |
extreme diffraction management in phase-corrected gradient metasurface by fourier harmonic component engineering |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/170307 |
| _version_ |
1779156298154115072 |