Si metasurface half-wave plates demonstrated on a 12-inch CMOS platform

Dong, Yuan; Xu, Zhengji; Li, Nanxi; Tong, Jianhua; Fu, Yuan Hsing; Zhou, Yanyan; Hu, Ting; Zhong, Qize; Bliznetsov, Vladimir; Zhu, Shiyang; Lin, Qunying; Zhang, Dao Hua; Gu, Yuandong; Singh, Navab

doi:10.1515/nanoph-2019-0364

Cited by 38 publications

(21 citation statements)

References 24 publications

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“…Existing optical waveplates require a large volume to accumulate the required phase differences for various polarizations. A metasurface-based half-wave plate (HWP) was fabricated with a 12 inch feature size by DUV photolithography ( Figure 2 f) [ 71 ]. The polarization conversion efficiency, which indicates the primary figure of merit for a HWP, is defined as

, where

and

are cross- and co-polarized transmittances, respectively.…”

Section: Optical Methodsmentioning

confidence: 99%

“…(e) (i) Schematic of a reflective scanning microscopy using the metalens, (ii) the measured image of the United States Air Force resolution chart and (iii) a Siemens star using this reflective scanning microscopy. (f) (i) Photograph of a 12 in Si metasurface, (ii) schematic of a measurement system of Fourier-transform infrared (FT-IR) spectroscopy using the metasurface-based half-wave plate (HWP)[71]. (g) (i) Photograph of a centimeter-scale perfect absorber fabricated by photolithography, (ii) simulated and experimental spectra of the perfect absorber[74].…”

mentioning

confidence: 99%

“…(g) (i) Photograph of a centimeter-scale perfect absorber fabricated by photolithography, (ii) simulated and experimental spectra of the perfect absorber[74]. Reproduced with permission from (a,b)[69]; ACS Publications, 2019, (c-e)[70]; Copyright 2019 American Chemical Society, (f)[71]; De Gruyter, 2012, and (g)[74]; Royal Society of Chemistry, 2015.…”

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confidence: 99%

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Scalable and High-Throughput Top-Down Manufacturing of Optical Metasurfaces

Lee

et al. 2020

Sensors

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Metasurfaces have shown promising potential to miniaturize existing bulk optical components thanks to their extraordinary optical properties and ultra-thin, small, and lightweight footprints. However, the absence of proper manufacturing methods has been one of the main obstacles preventing the practical application of metasurfaces and commercialization. Although a variety of fabrication techniques have been used to produce optical metasurfaces, there are still no universal scalable and high-throughput manufacturing methods that meet the criteria for large-scale metasurfaces for device/product-level applications. The fundamentals and recent progress of the large area and high-throughput manufacturing methods are discussed with practical device applications. We systematically classify various top-down scalable patterning techniques for optical metasurfaces: firstly, optical and printing methods are categorized and then their conventional and unconventional (emerging/new) techniques are discussed in detail, respectively. In the end of each section, we also introduce the recent developments of metasurfaces realized by the corresponding fabrication methods.

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, where

and

are cross- and co-polarized transmittances, respectively.…”

Section: Optical Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

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Scalable and High-Throughput Top-Down Manufacturing of Optical Metasurfaces

Lee

et al. 2020

Sensors

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“…In the near future, research and development efforts can be focused on the following three aspects, to facilitate the miniaturization of the multispectral/hyperspectral imaging and LIDAR systems. Firstly, with the demonstration of various metasurface-based functional devices, especially the spectral filters [169][170][171][172][173][174][175], it is expected to have more system-level integration of these devices (e.g., monolithic integration with CIS), to achieve compact spectral imaging systems. The monolithic fabrication process can be developed based on the mature CMOS fabrication technology.…”

Section: Discussionmentioning

confidence: 99%

Spectral imaging and spectral LIDAR systems: moving toward compact nanophotonics-based sensing

Wang

et al. 2021

Nanophotonics

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With the emerging trend of big data and internet-of-things, sensors with compact size, low cost and robust performance are highly desirable. Spectral imaging and spectral LIDAR systems enable measurement of spectral and 3D information of the ambient environment. These systems have been widely applied in different areas including environmental monitoring, autonomous driving, biomedical imaging, biometric identification, archaeology and art conservation. In this review, modern applications of state-of-the-art spectral imaging and spectral LIDAR systems in the past decade have been summarized and presented. Furthermore, the progress in the development of compact spectral imaging and LIDAR sensing systems has also been reviewed. These systems are based on the nanophotonics technology. The most updated research works on subwavelength scale nanostructure-based functional devices for spectral imaging and optical frequency comb-based LIDAR sensing works have been reviewed. These compact systems will drive the translation of spectral imaging and LIDAR sensing from table-top toward portable solutions for consumer electronics applications. In addition, the future perspectives on nanophotonics-based spectral imaging and LIDAR sensing are also presented.

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“…Such metasurface-based flat devices represent a new class of optical components that are compact, flat, and lightweight. Numerous devices based on metasurfaces have been developed, including metasurface lenses (metalenses) [9][10][11][12][13][14][15][16][17][18][19], waveplates [20][21][22][23], polarimeters [24][25][26], and holograms [27][28][29]. For metalenses, in particular, numerical aperture (NA) as high as 0.97 was demonstrated [15].…”

Section: Introductionmentioning

confidence: 99%

Metasurfaces for biomedical applications: imaging and sensing from a nanophotonics perspective

et al. 2020

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Metasurface is a recently developed nanophotonics concept to manipulate the properties of light by replacing conventional bulky optical components with ultrathin (more than 104 times thinner) flat optical components. Since the first demonstration of metasurfaces in 2011, they have attracted tremendous interest in the consumer optics and electronics industries. Recently, metasurface-empowered novel bioimaging and biosensing tools have emerged and been reported. Given the recent advances in metasurfaces in biomedical engineering, this review article covers the state of the art for this technology and provides a comprehensive interdisciplinary perspective on this field. The topics that we have covered include metasurfaces for chiral imaging, endoscopic optical coherence tomography, fluorescent imaging, super-resolution imaging, magnetic resonance imaging, quantitative phase imaging, sensing of antibodies, proteins, DNAs, cells, and cancer biomarkers. Future directions are discussed in twofold: application-specific biomedical metasurfaces and bioinspired metasurface devices. Perspectives on challenges and opportunities of metasurfaces, biophotonics, and translational biomedical devices are also provided. The objective of this review article is to inform and stimulate interdisciplinary research: firstly, by introducing the metasurface concept to the biomedical community; and secondly by assisting the metasurface community to understand the needs and realize the opportunities in the medical fields. In addition, this article provides two knowledge boxes describing the design process of a metasurface lens and the performance matrix of a biosensor, which serve as a “crash-course” introduction to those new to both fields.

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Si metasurface half-wave plates demonstrated on a 12-inch CMOS platform

Cited by 38 publications

References 24 publications

Scalable and High-Throughput Top-Down Manufacturing of Optical Metasurfaces

Scalable and High-Throughput Top-Down Manufacturing of Optical Metasurfaces

Spectral imaging and spectral LIDAR systems: moving toward compact nanophotonics-based sensing

Metasurfaces for biomedical applications: imaging and sensing from a nanophotonics perspective

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