Metasurface-based computer generated holography at terahertz frequencies

Liu Xingbo; Wang Qiu; Xu Quan; Zhang Xueqian; Xu Yuehong; Zhang Weili; Han Jiaguang

doi:10.12086/oee.2020.190674

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Liu X B, Wang Q, Xu Q, et al. Metasurface-based computer generated holography at terahertz frequencies[J]. Opto-Electron Eng, 2020, 47(5): 190674. doi: 10.12086/oee.2020.190674

Citation:

Liu X B, Wang Q, Xu Q, et al. Metasurface-based computer generated holography at terahertz frequencies[J]. Opto-Electron Eng, 2020, 47(5): 190674. doi: 10.12086/oee.2020.190674

Metasurface-based computer generated holography at terahertz frequencies

Center for THz Waves, College of Precision Instrument and Optoelectronics Engineering, Tianjin University, Tianjin 300072, China

Fund Project: Supported by Guangxi Key Laboratory of Automatic Detecting Technology and Instruments (YQ18205)

More Information

^*Corresponding author: Xu Quan, E-mail:quanxu@tju.edu.cn

Received Date 05 November 2019

Revised Date 09 January 2020

Published Date 01 May 2020

Abstract

Abstract

Holography is a kind of technique enabling 3D imaging which has been applied in many practical fields. With the rapid development of computer science and technology, computer generated holography (CGH) has become a common holography design method due to its high convenience and flexibility. Herein, we present a review of our recent progress in metasurface-based terahertz CGH. In these demonstrations, the metasurfaces acting as the holograms have shown the novel capabilities beyond the conventional counterparts. We first present a meta-hologram with simultaneous and independent phase and amplitude control over each pixel, which enables high-quality holographic imaging. Such new characteristic also predicts new holographic imaging performances including holographic images transforming continuously along the propagation direction realized by dielectric metasurface. Then different responses under different incident polarization states are designed. A linear polarization and frequency multiplexed meta-hologram, a reflective circular polarization multiplexed meta-hologram, and a surface-wave-based polarization multiplexed meta-hologram have been achieved respectively. Furthermore, a thermally dependent dynamic meta-hologram which can change the holographic image actively is also given. The proposed method paves a novel way to the design and realization of CGH functional devices in the future and contributes to the development of metasurfaces towards practical applications.
- terahertz /
- computer generated holography /
- metasurface /
- multiplexing

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References

[1]	Mittleman D. Sensing with Terahertz Radiation[M]. Berlin: Springer-Verlag, 2003: 117-153. Google Scholar
[2]	Siegel P H. Terahertz technology[J]. IEEE Transactions on Microwave Theory and Techniques, 2002, 50(3): 910-928. doi: 10.1109/22.989974 CrossRef Google Scholar
[3]	Pendry J B. Negative refraction makes a perfect lens[J]. Physical Review Letters, 2000, 85(18): 3966-3969. doi: 10.1103/PhysRevLett.85.3966 CrossRef Google Scholar
[4]	Shelby R A, Smith D R, Schultz S. Experimental verification of a negative index of refraction[J]. Science, 2001, 292(5514): 77-79. doi: 10.1126/science.1058847 CrossRef Google Scholar
[5]	Zhang S, Park Y S, Li J S, et al. Negative refractive index in chiral metamaterials[J]. Physical Review Letters, 2009, 102(2): 023901. doi: 10.1103/PhysRevLett.102.023901 CrossRef Google Scholar
[6]	Silveirinha M, Engheta N. Tunneling of electromagnetic energy through subwavelength channels and bends using ε-near-zero materials[J]. Physical Review Letters, 2006, 97(15): 157403. doi: 10.1103/PhysRevLett.97.157403 CrossRef Google Scholar
[7]	Ergin T, Stenger N, Brenner P, et al. Three-dimensional invisibility cloak at optical wavelengths[J]. Science, 2010, 328(5976): 337-339. doi: 10.1126/science.1186351 CrossRef Google Scholar
[8]	Liang D C, Gu J Q, Han J G, et al. Robust large dimension terahertz cloaking[J]. Advanced Materials, 2012, 24(7): 916-921. doi: 10.1002/adma.201103890 CrossRef Google Scholar
[9]	Valentine J, Li J, Zentgraf T, et al. An optical cloak made of dielectrics[J]. Nature Materials, 2009, 8(7): 568-571. doi: 10.1038/nmat2461 CrossRef Google Scholar
[10]	Liu Z W, Lee H, Xiong Y, et al. Far-field optical hyperlens magnifying sub-diffraction-limited objects[J]. Science, 2007, 315(5819): 1686. doi: 10.1126/science.1137368 CrossRef Google Scholar
[11]	Casse B D F, Lu W T, Huang Y J, et al. Super-resolution imaging using a three-dimensional metamaterials nanolens[J]. Applied Physics Letters, 2010, 96(2): 023114. doi: 10.1063/1.3291677 CrossRef Google Scholar
[12]	Safavi-Naeini A H, Alegre T P M, Chan J, et al. Electromagnetically induced transparency and slow light with optomechanics[J]. Nature, 2011, 472(7341): 69-73. doi: 10.1038/nature09933 CrossRef Google Scholar
[13]	Gu J Q, Singh R, Liu X J, et al. Active control of electromagnetically induced transparency analogue in terahertz metamaterials[J]. Nature Communications, 2012, 3: 1151. doi: 10.1038/ncomms2153 CrossRef Google Scholar
[14]	Chen Y L, Analytis J G, Chu J H, et al. Experimental realization of a three-dimensional topological insulator, Bi₂Te₃[J]. Science, 2009, 325(5937): 178-181. doi: 10.1126/science.1173034 CrossRef Google Scholar
[15]	Chang C Z, Zhang J S, Feng X, et al. Experimental observation of the quantum anomalous Hall effect in a magnetic topological insulator[J]. Science, 2013, 340(6129): 167-170. doi: 10.1126/science.1234414 CrossRef Google Scholar
[16]	Ni X J, Kildishev A V, Shalaev V M. Metasurface holograms for visible light[J]. Nature Communications, 2013, 4: 2807. doi: 10.1038/ncomms3807 CrossRef Google Scholar
[17]	Zheng G X, Mühlenbernd H, Kenney M, et al. Metasurface holograms reaching 80% efficiency[J]. Nature Nanotechnology, 2015, 10(4): 308-312. doi: 10.1038/nnano.2015.2 CrossRef Google Scholar
[18]	Huang L L, Chen X Z, Mühlenbernd H, et al. Three-dimensional optical holography using a plasmonic metasurface[J]. Nature Communications, 2013, 4: 2808. doi: 10.1038/ncomms3808 CrossRef Google Scholar
[19]	Zheng J, Ye Z C, Sun N L, et al. Highly anisotropic metasurface: a polarized beam splitter and hologram[J]. Scientific Reports, 2014, 4: 6491. Google Scholar
[20]	Genevet P, Capasso F. Holographic optical metasurfaces: a review of current progress[J]. Reports on Progress in Physics, 2015, 78(2): 024401. doi: 10.1088/0034-4885/78/2/024401 CrossRef Google Scholar
[21]	Chen W T, Yang K Y, Wang C M, et al. High-efficiency broadband meta-hologram with polarization-controlled dual images[J]. Nano Letters, 2014, 14(1): 225-230. doi: 10.1021/nl403811d CrossRef Google Scholar
[22]	Huang Y W, Chen W T, Tsai W Y, et al. Aluminum plasmonic multicolor meta-hologram[J]. Nano Letters, 2015, 15(5): 3122-3127. doi: 10.1021/acs.nanolett.5b00184 CrossRef Google Scholar
[23]	Yifat Y, Eitan M, Iluz Z, et al. Highly efficient and broadband wide-angle holography using patch-dipole nanoantenna reflectarrays[J]. Nano Letters, 2014, 14(5): 2485-2490. doi: 10.1021/nl5001696 CrossRef Google Scholar
[24]	Aieta F, Genevet P, Kats M A, et al. Aberration-free ultrathin flat lenses and axicons at telecom wavelengths based on plasmonic metasurfaces[J]. Nano Letters, 2012, 12(9): 4932-4936. doi: 10.1021/nl302516v CrossRef Google Scholar
[25]	Chen X Z, Huang L L, Mühlenbernd H, et al. Dual-polarity plasmonic metalens for visible light[J]. Nature Communications, 2012, 3: 1198. doi: 10.1038/ncomms2207 CrossRef Google Scholar
[26]	Wang Q, Zhang X Q, Xu Y H, et al. A broadband metasurface‐based terahertz flat‐lens array[J]. Advanced Optical Materials, 2015, 3(6): 779-785. doi: 10.1002/adom.201400557 CrossRef Google Scholar
[27]	Cong L Q, Xu N N, Gu J Q, et al. Highly flexible broadband terahertz metamaterial quarter‐wave plate[J]. Laser & Photonics Reviews, 2014, 8(4): 626-632. Google Scholar
[28]	Yu N F, Aieta F, Genevet P, et al. A broadband, background-free quarter-wave plate based on plasmonic metasurfaces[J]. Nano Letters, 2012, 12(12): 6328-6333. doi: 10.1021/nl303445u CrossRef Google Scholar
[29]	Gabor D. A new microscopic principle[J]. Nature, 1948, 161(4098): 777-778. doi: 10.1038/161777a0 CrossRef Google Scholar
[30]	Leith E N, Upatnieks J. Reconstructed wavefronts and communication theory[J]. Journal of the Optical Society of America, 1962, 52(10): 1123-1130. doi: 10.1364/JOSA.52.001123 CrossRef Google Scholar
[31]	Lohmann A W, Paris D P. Binary fraunhofer holograms, generated by computer[J]. Applied Optics, 1967, 6(10): 1739-1748. doi: 10.1364/AO.6.001739 CrossRef Google Scholar
[32]	Zhang X Q, Tian Z, Yue W S, et al. Broadband terahertz wave deflection based on C‐shape complex metamaterials with phase discontinuities[J]. Advanced Materials, 2013, 25(33): 4567-4572. doi: 10.1002/adma.201204850 CrossRef Google Scholar
[33]	Arbabi A, Horie Y, Bagheri M, et al. Dielectric metasurfaces for complete control of phase and polarization with subwavelength spatial resolution and high transmission[J]. Nature Nanotechnology, 2015, 10(11): 937-943. doi: 10.1038/nnano.2015.186 CrossRef Google Scholar
[34]	Zhang H F, Zhang X Q, Xu Q, et al. High‐efficiency dielectric metasurfaces for polarization-dependent terahertz wavefront manipulation[J]. Advanced Optical Materials, 2018, 6(1): 1700773. doi: 10.1002/adom.201700773 CrossRef Google Scholar
[35]	Xu Q, Zhang X Q, Wei M Q, et al. Efficient metacoupler for complex surface plasmon launching[J]. Advanced Optical Materials, 2018, 6(5): 1701117. doi: 10.1002/adom.201701117 CrossRef Google Scholar
[36]	Devlin R C, Khorasaninejad M, Chen W T, et al. Broadband high-efficiency dielectric metasurfaces for the visible spectrum[J]. Proceedings of the National Academy of Sciences of the United States of America, 2016, 113(38): 10473-10478. doi: 10.1073/pnas.1611740113 CrossRef Google Scholar
[37]	Wang Q, Zhang X Q, Xu Y H, et al. Broadband metasurface holograms: toward complete phase and amplitude engineering[J]. Scientific Reports, 2016, 6: 32867. doi: 10.1038/srep32867 CrossRef Google Scholar
[38]	Deng Z L, Deng J H, Zhuang X, et al. Diatomic metasurface for vectorial holography[J]. Nano Letters, 2018, 18(5): 2885-2892. doi: 10.1021/acs.nanolett.8b00047 CrossRef Google Scholar
[39]	Mueller J P B, Rubin N A, Devlin R C, et al. Metasurface polarization optics: independent phase control of arbitrary orthogonal states of polarization[J]. Physical Review Letters, 2017, 118(11): 113901. doi: 10.1103/PhysRevLett.118.113901 CrossRef Google Scholar
[40]	Wen D D, Yue F Y, Li G X, et al. Helicity multiplexed broadband metasurface holograms[J]. Nature Communications, 2015, 6: 8241. doi: 10.1038/ncomms9241 CrossRef Google Scholar
[41]	Wang Q, Plum E, Yang Q L, et al. Reflective chiral meta-holography: multiplexing holograms for circularly polarized waves[J]. Light: Science & Applications, 2018, 7(1): 25. Google Scholar
[42]	Ye W M, Zeuner F, Li X, et al. Spin and wavelength multiplexed nonlinear metasurface holography[J]. Nature Communications, 2016, 7: 11930. doi: 10.1038/ncomms11930 CrossRef Google Scholar
[43]	Almeida E, Bitton O, Prior Y. Nonlinear metamaterials for holography[J]. Nature Communications, 2016, 7: 12533. doi: 10.1038/ncomms12533 CrossRef Google Scholar
[44]	Wang Q, Xu Q, Zhang X Q, et al. All-dielectric meta-holograms with holographic images transforming longitudinally[J]. ACS Photonics, 2018, 5(2): 599-606. doi: 10.1021/acsphotonics.7b01173 CrossRef Google Scholar
[45]	Wang Q, Zhang X Q, Plum E, et al. Polarization and frequency multiplexed terahertz meta‐holography[J]. Advanced Optical Materials, 2017, 5(14): 1700277. doi: 10.1002/adom.201700277 CrossRef Google Scholar
[46]	Xu Q, Zhang X Q, Xu Y H, et al. Polarization‐controlled surface plasmon holography[J]. Laser & Photonics Reviews, 2017, 11(1): 1600212. Google Scholar
[47]	Liu X B, Wang Q, Zhang X Q, et al. Thermally dependent dynamic meta‐holography using a vanadium dioxide integrated metasurface[J]. Advanced Optical Materials, 2019, 7(12): 1900175. doi: 10.1002/adom.201900175 CrossRef Google Scholar
[48]	Wang B, Quan B G, He J W, et al. Wavelength de-multiplexing metasurface hologram[J]. Scientific Reports, 2016, 6: 35657. doi: 10.1038/srep35657 CrossRef Google Scholar
[49]	Gerchberg R W, Saxton W O. A practical algorithm for the determination of phase from image and diffraction plane pictures[J]. Optik, 1972, 35(2): 237-246. Google Scholar
[50]	Guo J Y, Wang T, Zhao H, et al. Reconfigurable terahertz metasurface pure phase holograms[J]. Advanced Optical Materials, 2019, 7(10): 1801696. doi: 10.1002/adom.201801696 CrossRef Google Scholar

Overview

Overview

Overview: We review our recent progress in metasurface-based terahertz computer generated holography in which metasurfaces act as the holograms and show novel advantages.

To get better quality of holographic image, the unit should modulate both amplitude and phase of incidence rather than just one of them. Based on the different resonance modes caused by parallel polarization incidence and perpendicular polarization incidence, a series of different C-shape split-ring resonators (CSRRs) are designed which have different modulating effects with each other in y-polarized transmittance and phase shift spectra under x-polarized normal incidence.

Although a fine hologram can be composed by CSRRs, its energy efficiency is low. To solve this problem, we resort to the all-dielectric metasurface. Its units are silicon pillar resonators which not only own the high energy efficiency but also can modulate both amplitude and phase of incidence like CSRRs.

To improve utilization efficiency of holograms, the multiplexed metasuface is one of the ideal solutions. The multiplexed holograms can increase information capacity of imaging system and make it more simplified. For these reasons, some multiplexed meta-holograms emerged in our works.

Firstly, a meta-hologram which is a linear polarization and frequency multiplexed one is designed. On the hologram, two sets of CSRRs which work at different frequencies are arranged and a pattern like checkerboard formed. Due to special design some CSRRs do not work when others do. Based on CSRRs working at different frequencies and the special arrangement, the linear polarization and frequency multiplexed hologram is achieved.

Secondly, a circular polarization multiplexed hologram is realized. There are two types of units on it which are L-type DSRRs (double-split ring resonators) and R-type DSRRs respectively and they response to the left-handed or right-handed circular polarization only. Based on the Pancharatnam-Berry phase and a modified Gerchberg-Saxton algorithm, the hologram shows different holographic images under left-handed and right-handed circular polarization incidence, respectively.

Thirdly, a surface plasmon holography which is polarization multiplexed is also achieved. On these holograms, slit-pair resonators act as the pixels. The holographic images are composed by a series of surface plasmon which excited by different pixels. The initial phase of surface plasmon from pixels is depended on the origin of the slit-pair resonator and the polarization of incidence.

Finally, a thermally dependent active control meta-hologram is also designd and demonstrated in experiment. There are two sets of units on it which are passive units and active units. They are CSRRs and V-CSRRs (vanadium dioxide integrated CSRRs) which are CSRRs contained vanadium dioxide in their gaps. Based on the phase transition effect of vanadium dioxide andreasonable arrangement of passive and active units and destructive interference images showed by them, the hologram shows different holographic images in low and high temperatures, respectively.