Your search keyword '"optical metasurface"' showing total 38 results

1. All-dielectric bifocal metalens with diffraction-limited focusing and polarization-dependent characteristics

Author

Gao, Xuyang, Liu, Yuxin, Chen, Hao, Lin, Yu-Sheng, and Chen, Xuequan

Published

2025

2. Exceptional‐Point‐Enhanced Superior Sensing Using Asymmetric Coupled‐Lossy‐Resonator Based Optical Metasurface.

Author

Nag Chowdhury, Basudev, Lahiri, Pooja, Johnson, Nigel P., De La Rue, Richard M., and Lahiri, Basudev

Subjects

*THERMAL noise, *SARS-CoV-2 Omicron variant, *LASERS, *TOPOLOGY, *MOLECULES

Abstract

Exotic optical responses of designed metasurfaces, including non‐Hermitian photonic systems exhibiting exceptional point (EP)‐singularities, offer diverse applications in the field of quantum sensing, laser technology, gravitational‐wave detection as well as biomedical instrumentation for weak signal detection. However, the sensitivity enhancement of such EP‐sensors is limited by quantum/thermal noises. Here we propose a novel scheme of EP‐based superior photonic sensing of any molecule, using suitably designed asymmetric coupled‐lossy‐resonators (ACLR) with a non‐Hermitian Hamiltonian. Unlike conventional approach of EP‐degeneracy lifting, the perturbing Hamiltonian of the molecular‐vibron, in the present method, generates an EP‐singularity by coupling with the ACLR that does not exhibit EP in the unperturbed condition. Raman spectroscopic measurements performed on such systems provide significantly enhanced peaks at the vibronic modes, thereby exploring a novel method for molecule detection with superior sensitivity. Such EP‐sensing is experimentally demonstrated in the current work by detecting the relevant protein‐vibrons of the recombinant Omicron strain of SARS‐CoV‐2 with 350%‐2200% enhanced Raman intensities, using an optical‐metasurface consisting of an array of Au‐asymmetric split‐ring‐resonators as the ACLRs. This work will open up a novel field of EP‐based superior photonic sensing of any molecule, in general, by appropriately designing the ACLR‐structures for detecting molecular‐vibrons with desired enhanced sensitivity. [ABSTRACT FROM AUTHOR]

Published

2024

3. Dual-Channel Switchable Metasurface Filters for Compact Spectral Imaging with Deep Compressive Reconstruction.

Author

Wang, Chang, Liu, Xinyu, Zhang, Yang, Sun, Yan, Yu, Zeqing, and Zheng, Zhenrong

Subjects

*SPECTRAL imaging, *NEMATIC liquid crystals, *OBJECT recognition (Computer vision), *IMAGING systems, *LINEAR polarization, *IMAGE sensors

Abstract

Spectral imaging technology, which aims to capture images across multiple spectral channels and create a spectral data cube, has been widely utilized in various fields. However, conventional spectral imaging systems face challenges, such as slow acquisition speed and large size. The rapid development of optical metasurfaces, capable of manipulating light fields versatilely and miniaturizing optical components into ultrathin planar devices, offers a promising solution for compact hyperspectral imaging (HSI). This study proposes a compact snapshot compressive spectral imaging (SCSI) system by leveraging the spectral modulations of metasurfaces with dual-channel switchable metasurface filters and employing a deep-learning-based reconstruction algorithm. To achieve compactness, the proposed system integrates dual-channel switchable metasurface filters using twisted nematic liquid crystals (TNLCs) and anisotropic titanium dioxide (TiO2) nanostructures. These thin metasurface filters are closely attached to the image sensor, resulting in a compact system. The TNLCs possess a broadband linear polarization conversion ability, enabling the rapid switching of the incidence polarization state between x-polarization and y-polarization by applying different voltages. This polarization conversion facilitates the generation of two groups of transmittance spectra for wavelength-encoding, providing richer information for spectral data cube reconstruction compared to that of other snapshot compressive spectral imaging techniques. In addition, instead of employing classic iterative compressive sensing (CS) algorithms, an end-to-end residual neural network (ResNet) is utilized to reconstruct the spectral data cube. This neural network leverages the 2-frame snapshot measurements of orthogonal polarization channels. The proposed hyperspectral imaging technology demonstrates superior reconstruction quality and speed compared to those of the traditional compressive hyperspectral image recovery methods. As a result, it is expected that this technology will have substantial implications in various domains, including but not limited to object detection, face recognition, food safety, biomedical imaging, agriculture surveillance, and so on. [ABSTRACT FROM AUTHOR]

Published

2023

4. Dual-Functional Tunable Metasurface for Meta-Axicon with a Variable Depth of Focus and Continuous-Zoom Metalens.

Author

Wang, Chang, Sun, Yan, Yu, Zeqing, Liu, Xinyu, Chen, Bingliang, Zhang, Yang, and Zheng, Zhenrong

Subjects

*BESSEL beams, *NUMERICAL apertures, *FOCAL length, *GEOMETRIC quantum phases, *PHASE modulation, *WAVEFRONTS (Optics)

Abstract

Optical metasurfaces have been widely investigated for their versatile ability to manipulate wavefront and miniaturize traditional optical components into ultrathin planar devices. The integration of metasurfaces with multifunctionality and tunability has fundamentally transformed optics with unprecedented control over light propagation and manipulation. This study introduces a pioneering framework for the development of tunable metasurfaces with multifunctionality, and an example of a tunable metasurface of dual functionalities is proposed and numerically verified as one of the tunable meta-axicon for generating Bessel beams with a variable depth of focus (DOF) and a continuous-zoom metalens. Specifically, this design achieves dual-functional phase modulation by helicity-multiplexing from the combination of the geometric phase as well as the propagation phase and realizes tunability for both functionalities through rotational actuation between double metasurface layers. As a result, dual functionalities with continuous tunability of the proposed TiO2 metasurface are enabled independently for the left and right circularly polarized (LCP and RCP) incidences at 532 nm. Specifically, LCP light triggers the metasurface to function as a tunable axicon, generating non-diffracting Bessel beams with variable numerical apertures (NA) and DOFs. Conversely, the RCP incidence induces it to operate as a continuous-zoom metalens and generates variable spherical wavefront focusing on diverse focal lengths. This study not only initially implements the design of tunable meta-axicon, but also achieves the integration of such a tunable meta-axicon and continuous-zoom metalens within a single metasurface configuration. The proposed device could find potential applications in biological imaging, microscopic measurement, laser fabrication, optical manipulation, multi-plane imaging, depth estimation, optical data storage, etc. [ABSTRACT FROM AUTHOR]

Published

2023

5. Structural color generation: from layered thin films to optical metasurfaces

Author

Wang Danyan, Liu Zeyang, Wang Haozhu, Li Moxin, Guo L. Jay, and Zhang Cheng

Subjects

structural color, optical metasurface, fabry pérot resonance, guided mode resonance, plasmon resonance, mie resonance, Physics, QC1-999

Abstract

Recent years have witnessed a rapid development in the field of structural coloration, colors generated from the interaction of nanostructures with light. Compared to conventional color generation based on pigments and dyes, structural color generation exhibits unique advantages in terms of spatial resolution, operational stability, environmental friendliness, and multiple functionality. Here, we discuss recent development in structural coloration based on layered thin films and optical metasurfaces. This review first presents fundamentals of color science and introduces a few popular color spaces used for color evaluation. Then, it elaborates on representative physical mechanisms for structural color generation, including Fabry–Pérot resonance, photonic crystal resonance, guided mode resonance, plasmon resonance, and Mie resonance. Optimization methods for efficient structure parameter searching, fabrication techniques for large-scale and low-cost manufacturing, as well as device designs for dynamic displaying are discussed subsequently. In the end, the review surveys diverse applications of structural colors in various areas such as printing, sensing, and advanced photovoltaics.

Published

2023

6. Temperature Self-Adaptive Ultra-Thin Solar Absorber Based on Optimization Algorithm.

Author

Chen, Jian, Li, Xin, Chen, Yutai, Zhang, Zhaojian, Yu, Yang, He, Xin, Chen, Huan, Yang, Junbo, Zhang, Zhenfu, and Yao, Xiaopeng

Subjects

OPTIMIZATION algorithms, SOLAR thermal energy, SOLAR heating, HELIOSPHERE, SOLAR energy, SOLAR radiation

Abstract

In solar applications, the solar absorber is paramount to converting solar radiation to heat energy. We systematically examined the relationship between the efficiency of the solar absorber and operating temperature and other factors. By combining inverse designs with surface plasmonic and Fabry-Perot cavity solar absorption theories, we have developed several solar absorber devices with excellent performance at different temperatures. One of these devices displays a solar spectral absorption of 95.6%, an ultra-low emission rate of 5.7%, and optical-to-thermal conversion efficiency exceeding 90%, all within an ultra-thin depth of 0.45 μm under working temperatures of 600 K. The device has the potential to surpass the Shockley-Queisser limit (S-Q limit) in solar power generation systems. Our method is adaptable, enabling the design of optimal-performance devices to the greatest extent possible. The design was optimized using modern optimization algorithms to meet complex conditions and offers new insights for further study of the conversion from solar to thermal energy and the advancement of solar energy applications. [ABSTRACT FROM AUTHOR]

Published

2023

7. Coupled Plasmon Wave Dynamics beyond Anomalous Reflection: A Phase Gradient Copper Metasurface for the Visible to Near-Infrared Spectrum

Author

Hosna Sultana

Subjects

optical metasurface, SPP wave, plasmonic band structure, Optics. Light, QC350-467, Applied optics. Photonics, TA1501-1820

Abstract

In nanoscale photonic devices, the demand for multifunctionality from 2D metasurface optics has increased rapidly. To explore the required fine-tuning in the design metrics, we reinvestigated the trapezoid-shape copper metasurface using finite-difference time-domain simulation to efficiently utilize linearly polarized light for two different functionalities. From the plasmonic band structure, we could see how the degree of asymmetry in the geometry affected the efficient resonance coupling of the traveling plasmonic modes, along with the different types of mode hybridization profiles that were related to the nanoantenna’s geometric shape. By tuning the nanoantenna’s length, we could excite the effective plasmon mode that was supported by this configuration and guide surface waves unidirectionally from the normal incidence free-space light within the visible to infrared range. The directed surface plasmon polaritons had both antisymmetric and symmetric modes that oscillated between the top and bottom surfaces of the continuous metal layer, depending on the nanoantenna’s length and wavelength. This proposed copper metasurface was optimized for a far-field application of broadband (600–900 nm) anomalous beam steering for an average of 60% efficiency with a maximum angle of 64°. This work offers more understanding of a metasurface being implemented in small plasmonic devices, waveguide mode controlling and beam steering with wavelength-dependent functionalities.

Published

2022

8. Recent progress in metasurface-enabled optical waveplates

Author

Deng Yadong, Cai Ziru, Ding Yingtao, Bozhevolnyi Sergey I., and Ding Fei

Subjects

dynamic, multifunctional, optical metasurface, waveplates, Physics, QC1-999

Abstract

The polarization of light is crucial for numerous optical applications ranging from quantum information processing to biomedical sensing due to the fundamental role of polarization as another intrinsic characteristic of optical waves, which is uncorrelated with the amplitude, phase, and frequency. However, conventional optical waveplates that enable polarization control are based on the accumulated retardation between two orthogonally polarized electric fields when light propagates a distance much larger than its wavelength in birefringent materials, resulting in bulky configurations and limited functionalities. Optical metasurfaces, ultrathin arrays of engineered meta-atoms, have attracted increasing attention owing to their unprecedented capabilities of manipulating light with surface-confined configurations and subwavelength spatial resolutions, thereby opening up new possibilities for revolutionizing bulky optical waveplates with ultrathin planar elements that feature compactness, integration compatibility, broadband operation bandwidths, and multiple functionalities. Herein, we review the recent progress in metasurface-enabled optical waveplates, which covers both basic principles and emerging applications. We provide an overview of metasurface-based conventional half- and quarter-waveplates as well as their use in wavefront shaping applications, followed by a discussion of advanced waveplates, including multifunctional waveplates and all-polarization generators. We also discuss dynamic waveplates based on active metasurfaces. Finally, we conclude by providing our outlook in this emerging and fast-growing research field.

Published

2022

9. Optical metasurfaces towards multifunctionality and tunability

Author

Du Kang, Barkaoui Hamdi, Zhang Xudong, Jin Limin, Song Qinghai, and Xiao Shumin

Subjects

multifunctional, optical metasurface, reconfigurable, tunable, Physics, QC1-999

Abstract

Optical metasurfaces is a rapidly developing research field driven by its exceptional applications for creating easy-to-integrate ultrathin planar optical devices. The tight confinement of the local electromagnetic fields in resonant photonic nanostructures can boost many optical effects and offer novel opportunities for the nanoscale control of light–matter interactions. However, once the structure-only metasurfaces are fabricated, their functions will be fixed, which limits it to make breakthroughs in practical applications. Recently, persistent efforts have led to functional multiplexing. Besides, dynamic light manipulation based on metasurfaces has been demonstrated, providing a footing ground for arbitrary light control in full space-time dimensions. Here, we review the latest research progress in multifunctional and tunable metasurfaces. Firstly, we introduce the evolution of metasurfaces and then present the concepts, the basic principles, and the design methods of multifunctional metasurface. Then with more details, we discuss how to realize metasurfaces with both multifunctionality and tunability. Finally, we also foresee various future research directions and applications of metasurfaces including innovative design methods, new material platforms, and tunable metasurfaces based metadevices.

Published

2022

10. Dual-Channel Switchable Metasurface Filters for Compact Spectral Imaging with Deep Compressive Reconstruction

Author

Chang Wang, Xinyu Liu, Yang Zhang, Yan Sun, Zeqing Yu, and Zhenrong Zheng

Subjects

optical metasurface, hyperspectral imaging, deep learning, Chemistry, QD1-999

Abstract

Spectral imaging technology, which aims to capture images across multiple spectral channels and create a spectral data cube, has been widely utilized in various fields. However, conventional spectral imaging systems face challenges, such as slow acquisition speed and large size. The rapid development of optical metasurfaces, capable of manipulating light fields versatilely and miniaturizing optical components into ultrathin planar devices, offers a promising solution for compact hyperspectral imaging (HSI). This study proposes a compact snapshot compressive spectral imaging (SCSI) system by leveraging the spectral modulations of metasurfaces with dual-channel switchable metasurface filters and employing a deep-learning-based reconstruction algorithm. To achieve compactness, the proposed system integrates dual-channel switchable metasurface filters using twisted nematic liquid crystals (TNLCs) and anisotropic titanium dioxide (TiO2) nanostructures. These thin metasurface filters are closely attached to the image sensor, resulting in a compact system. The TNLCs possess a broadband linear polarization conversion ability, enabling the rapid switching of the incidence polarization state between x-polarization and y-polarization by applying different voltages. This polarization conversion facilitates the generation of two groups of transmittance spectra for wavelength-encoding, providing richer information for spectral data cube reconstruction compared to that of other snapshot compressive spectral imaging techniques. In addition, instead of employing classic iterative compressive sensing (CS) algorithms, an end-to-end residual neural network (ResNet) is utilized to reconstruct the spectral data cube. This neural network leverages the 2-frame snapshot measurements of orthogonal polarization channels. The proposed hyperspectral imaging technology demonstrates superior reconstruction quality and speed compared to those of the traditional compressive hyperspectral image recovery methods. As a result, it is expected that this technology will have substantial implications in various domains, including but not limited to object detection, face recognition, food safety, biomedical imaging, agriculture surveillance, and so on.

Published

2023

11. Dual-Functional Tunable Metasurface for Meta-Axicon with a Variable Depth of Focus and Continuous-Zoom Metalens

Author

Chang Wang, Yan Sun, Zeqing Yu, Xinyu Liu, Bingliang Chen, Yang Zhang, and Zhenrong Zheng

Subjects

optical metasurface, tunability, multifunctionality, axicon, Bessel beam, zoom metalens, Chemistry, QD1-999

Abstract

Optical metasurfaces have been widely investigated for their versatile ability to manipulate wavefront and miniaturize traditional optical components into ultrathin planar devices. The integration of metasurfaces with multifunctionality and tunability has fundamentally transformed optics with unprecedented control over light propagation and manipulation. This study introduces a pioneering framework for the development of tunable metasurfaces with multifunctionality, and an example of a tunable metasurface of dual functionalities is proposed and numerically verified as one of the tunable meta-axicon for generating Bessel beams with a variable depth of focus (DOF) and a continuous-zoom metalens. Specifically, this design achieves dual-functional phase modulation by helicity-multiplexing from the combination of the geometric phase as well as the propagation phase and realizes tunability for both functionalities through rotational actuation between double metasurface layers. As a result, dual functionalities with continuous tunability of the proposed TiO2 metasurface are enabled independently for the left and right circularly polarized (LCP and RCP) incidences at 532 nm. Specifically, LCP light triggers the metasurface to function as a tunable axicon, generating non-diffracting Bessel beams with variable numerical apertures (NA) and DOFs. Conversely, the RCP incidence induces it to operate as a continuous-zoom metalens and generates variable spherical wavefront focusing on diverse focal lengths. This study not only initially implements the design of tunable meta-axicon, but also achieves the integration of such a tunable meta-axicon and continuous-zoom metalens within a single metasurface configuration. The proposed device could find potential applications in biological imaging, microscopic measurement, laser fabrication, optical manipulation, multi-plane imaging, depth estimation, optical data storage, etc.

Published

2023

12. Efficient generation of optical bottle beams

Author

Xiao Yuzhe, Yu Zhaoning, Wambold Raymond A., Mei Hongyan, Hickman Garrett, Goldsmith Randall H., Saffman Mark, and Kats Mikhail A.

Subjects

atom trap, optical bottle beam, optical metasurface, Physics, QC1-999

Abstract

Optical bottle beams can be used to trap atoms and small low-index particles. We introduce a figure of merit (FoM) for optical bottle beams, specifically in the context of optical traps, and use it to compare optical bottle-beam traps obtained by three different methods. Using this FoM and an optimization algorithm, we identified the optical bottle-beam traps based on a Gaussian beam illuminating a metasurface that are superior in terms of power efficiency than existing approaches. We numerically demonstrate a silicon metasurface for creating an optical bottle-beam trap.

Published

2021

13. Temperature Self-Adaptive Ultra-Thin Solar Absorber Based on Optimization Algorithm

Author

Jian Chen, Xin Li, Yutai Chen, Zhaojian Zhang, Yang Yu, Xin He, Huan Chen, Junbo Yang, Zhenfu Zhang, and Xiaopeng Yao

Subjects

the solar absorber, optical metasurface, optimization algorithm, Applied optics. Photonics, TA1501-1820

Abstract

In solar applications, the solar absorber is paramount to converting solar radiation to heat energy. We systematically examined the relationship between the efficiency of the solar absorber and operating temperature and other factors. By combining inverse designs with surface plasmonic and Fabry-Perot cavity solar absorption theories, we have developed several solar absorber devices with excellent performance at different temperatures. One of these devices displays a solar spectral absorption of 95.6%, an ultra-low emission rate of 5.7%, and optical-to-thermal conversion efficiency exceeding 90%, all within an ultra-thin depth of 0.45 μm under working temperatures of 600 K. The device has the potential to surpass the Shockley-Queisser limit (S-Q limit) in solar power generation systems. Our method is adaptable, enabling the design of optimal-performance devices to the greatest extent possible. The design was optimized using modern optimization algorithms to meet complex conditions and offers new insights for further study of the conversion from solar to thermal energy and the advancement of solar energy applications.

Published

2023

14. High-efficiency, large-area lattice light-sheet generation by dielectric metasurfaces

Author

Shi Fenghua, Wen Jing, and Lei Dangyuan

Subjects

field of view, illumination efficiency, lattice light-sheet microscopy, optical metasurface, spatial frequency manipulation, Physics, QC1-999

Abstract

Lattice light-sheet microscopy (LLSM) was developed for long-term live-cell imaging with ultra-fine three-dimensional (3D) spatial resolution, high temporal resolution, and low photo-toxicity by illuminating the sample with a thin lattice-like light-sheet. Currently available schemes for generating thin lattice light-sheets often require complex optical designs. Meanwhile, limited by the bulky objective lens and optical components, the light throughput of existing LLSM systems is rather low. To circumvent the above problems, we utilize a dielectric metasurface of a single footprint to replace the conventional illumination modules used in the conventional LLSM and generate a lattice light-sheet with a ~3-fold broader illumination area and a significantly leveraged illumination efficiency, which consequently leads to a larger field of view with a higher temporal resolution at no extra cost of the spatial resolution. We demonstrate that the metasurface can manipulate spatial frequencies of an input laser beam in orthogonal directions independently to break the trade-off between the field of view and illumination efficiency of the lattice light-sheet. Compared to the conventional LLSM, our metasurface module serving as an ultra-compact illumination component for LLSM at an ease will potentially enable a finer spatial resolution with a larger numerical-aperture detection objective lens.

Published

2020

15. Advances in exploiting the degrees of freedom in nanostructured metasurface design: from 1 to 3 to more

Author

Li Zile, Yu Shaohua, and Zheng Guoxing

Subjects

optical metasurface, geometric phase, holography, metalens, degrees of freedom, multifunctional device, Physics, QC1-999

Abstract

The unusual electromagnetic responses of nanostructured metasurfaces endow them with an ability to manipulate the four fundamental properties (amplitude, phase, polarization, and frequency) of lightwave at the subwavelength scale. Based on this, in the past several years, a lot of innovative optical elements and devices, such as metagratings, metalens, metaholograms, printings, vortex beam generators, or even their combinations, have been proposed, which have greatly empowered the advanced research and applications of metasurfaces in many fields. Behind these achievements are scientists’ continuous exploration of new physics and degrees of freedom in nanostructured metasurface design. This review will focus on the progress on the design of different nanostructured metasurfaces for lightwave manipulation, including by varying/fixing the dimensions and/or orientations of isotropic/anisotropic nanostructures, which can therefore provide various functionalities for different applications. Exploiting the design degrees of freedom of optical metasurfaces provides great flexibility in the design of multifunctional and multiplexing devices, which can be applied in anticounterfeiting, information encoding and hiding, high-density optical storage, multichannel imaging and displays, sensing, optical communications, and many other related fields.

Published

2020

16. Metasurface for Engineering Superimposed Ince-Gaussian Beams.

Author

Ahmed H, Ansari MA, Paterson L, Li J, and Chen X

Abstract

Ince-Gaussian beams (IGBs) are the third complete family of exact and orthogonal solutions of the paraxial wave equation and have been applied in many fields ranging from particle trapping to quantum optics. IGBs play a very important role in optics as they represent the exact and continuous transition modes connecting Laguerre-Gaussian and Hermite-Gaussian beams. The method currently in use suffers from the high cost, complexity, and large volume of the optical system. The superposition of IGBs can generate complicated structured beams with multiple phase and polarization singularities. A metasurface approach is proposed to realizing various superpositions of IGBs without relying on a complicated optical setup. By superimposing IGBs with even and odd modes, multiple phase, and polarization singularities are observed in the resultant beams. The phase and polarization singularities are modulated by setting the initial phase in the design and controlling the incident linear polarization. The compactness of the developed metasurface devices and the unique properties of the generated beams have the potential to impact many practical applications such as particle manipulation, orbital angular momentum spectrum manipulation, and optical communications., (© 2024 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

17. Nonconventional metasurfaces: from non-Hermitian coupling, quantum interactions, to skin cloak

Author

Ren Xuexin, Jha Pankaj K., Wang Yuan, and Zhang Xiang

Subjects

anti-hermitian, cloaking, optical metasurface, quantum vacuum engineering, spin-hall effect, Physics, QC1-999

Abstract

Metasurfaces are optically thin layers of subwavelength resonators that locally tailor the electromagnetic response at the nanoscale. Our metasurface research aims at developing novel designs and applications of metasurfaces that go beyond the classical regimes. In contrast to conventional phase gradient metasurfaces where each meta-atom responds individually, we are interested in developing metasurfaces where neighboring meta-atoms are strongly coupled. By engineering a non-Hermitian coupling between the meta-atoms, new degrees of freedom are introduced and novel functionalities can be achieved. We are also interested in combining classical metasurface with quantum emitters, which may offer opportunities for on-chip quantum technologies. Additionally, we have been designing metasurfaces to realize exciting phenomena and applications, such as ultrathin metasurface cloak and strong photonic spin-Hall effect. In this paper, we review our research efforts in optical metasurfaces in the past few years, which ranges from conventional to novel type of metasurface and from classical to quantum regime.

Published

2018

18. Efficient generation of optical bottle beams

Author

Mikhail A. Kats, Yuzhe Xiao, Raymond Wambold, Zhaoning Yu, Garrett Hickman, Hongyan Mei, Mark Saffman, and Randall H. Goldsmith

Subjects

optical metasurface, business.product_category, Silicon, atom trap, Atomic Physics (physics.atom-ph), QC1-999, FOS: Physical sciences, Physics::Optics, chemistry.chemical_element, Context (language use), Applied Physics (physics.app-ph), 02 engineering and technology, 01 natural sciences, Physics - Atomic Physics, 010309 optics, Trap (computing), Optics, 0103 physical sciences, Bottle, Figure of merit, Physics::Atomic Physics, Electrical and Electronic Engineering, Condensed Matter::Quantum Gases, Physics, optical bottle beam, Quantum Physics, Optimization algorithm, business.industry, Physics - Applied Physics, 021001 nanoscience & nanotechnology, Mathematics::Geometric Topology, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, chemistry, Physics::Accelerator Physics, Quantum Physics (quant-ph), 0210 nano-technology, business, Electrical efficiency, Physics - Optics, Optics (physics.optics), Biotechnology, Gaussian beam

Abstract

Optical bottle beams can be used to trap atoms and small low-index particles. We introduce a figure of merit for optical bottle beams, specifically in the context of optical traps, and use it to compare optical bottle-beam traps obtained by three different methods. Using this figure of merit and an optimization algorithm, we identified optical bottle-beam traps based on a Gaussian beam illuminating a metasurface that are superior in terms of power efficiency than existing approaches. We numerically demonstrate a silicon metasurface for creating an optical bottle-beam trap., Comment: Main text + supplementary

Published

2021

19. High-efficiency, large-area lattice light-sheet generation by dielectric metasurfaces

Author

Fenghua Shi, Jing Wen, and Dangyuan Lei

Subjects

optical metasurface, 0303 health sciences, Materials science, spatial frequency manipulation, Condensed matter physics, illumination efficiency, Physics, QC1-999, Physics::Optics, 02 engineering and technology, Dielectric, Lattice light-sheet microscopy, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Nanomaterials, 03 medical and health sciences, Lattice (order), lattice light-sheet microscopy, Electrical and Electronic Engineering, field of view, 0210 nano-technology, 030304 developmental biology, Biotechnology

Abstract

Lattice light-sheet microscopy (LLSM) was developed for long-term live-cell imaging with ultra-fine three-dimensional (3D) spatial resolution, high temporal resolution, and low photo-toxicity by illuminating the sample with a thin lattice-like light-sheet. Currently available schemes for generating thin lattice light-sheets often require complex optical designs. Meanwhile, limited by the bulky objective lens and optical components, the light throughput of existing LLSM systems is rather low. To circumvent the above problems, we utilize a dielectric metasurface of a single footprint to replace the conventional illumination modules used in the conventional LLSM and generate a lattice light-sheet with a ~3-fold broader illumination area and a significantly leveraged illumination efficiency, which consequently leads to a larger field of view with a higher temporal resolution at no extra cost of the spatial resolution. We demonstrate that the metasurface can manipulate spatial frequencies of an input laser beam in orthogonal directions independently to break the trade-off between the field of view and illumination efficiency of the lattice light-sheet. Compared to the conventional LLSM, our metasurface module serving as an ultra-compact illumination component for LLSM at an ease will potentially enable a finer spatial resolution with a larger numerical-aperture detection objective lens.

Published

2020

20. Advances in exploiting the degrees of freedom in nanostructured metasurface design: from 1 to 3 to more

Author

Zile Li, Shaohua Yu, and Guoxing Zheng

Subjects

Physics, optical metasurface, QC1-999, Degrees of freedom, Holography, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Atomic and Molecular Physics, and Optics, metalens, Electronic, Optical and Magnetic Materials, law.invention, 010309 optics, Classical mechanics, geometric phase, Geometric phase, law, degrees of freedom, multifunctional device, 0103 physical sciences, holography, Electrical and Electronic Engineering, 0210 nano-technology, Biotechnology

Abstract

The unusual electromagnetic responses of nanostructured metasurfaces endow them with an ability to manipulate the four fundamental properties (amplitude, phase, polarization, and frequency) of lightwave at the subwavelength scale. Based on this, in the past several years, a lot of innovative optical elements and devices, such as metagratings, metalens, metaholograms, printings, vortex beam generators, or even their combinations, have been proposed, which have greatly empowered the advanced research and applications of metasurfaces in many fields. Behind these achievements are scientists’ continuous exploration of new physics and degrees of freedom in nanostructured metasurface design. This review will focus on the progress on the design of different nanostructured metasurfaces for lightwave manipulation, including by varying/fixing the dimensions and/or orientations of isotropic/anisotropic nanostructures, which can therefore provide various functionalities for different applications. Exploiting the design degrees of freedom of optical metasurfaces provides great flexibility in the design of multifunctional and multiplexing devices, which can be applied in anticounterfeiting, information encoding and hiding, high-density optical storage, multichannel imaging and displays, sensing, optical communications, and many other related fields.

Published

2020

21. PCM-net: a refractive index database of chalcogenide phase change materials for tunable nanophotonic device modelling

Author

Kim, Hyun Jung, Sohn, Jung-Woo, Hong, Nina, Williams, Calum, Humphreys, William, Kim, Hyun Jung [0000-0003-0448-7699], Williams, Calum [0000-0002-6432-6515], Apollo - University of Cambridge Repository, Kim, HJ [0000-0003-0448-7699], and Williams, C [0000-0002-6432-6515]

Subjects

Paper, Condensed Matter - Materials Science, optical metasurface, refractive index, online database, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Focus on Phase Change Materials for Photonics, PCM-net, device modelling, nanophotonics, phase change material, Physics - Optics, Optics (physics.optics)

Abstract

Recently, chalcogenide glass based phase change materials (PCMs) have shown utility as a tuning material for a range of nanophotonic devices. Owing to their low loss, ultrafast switching speeds and wide waveband operation, PCMs are integrated in an increasing number of next generation tunable components, including integrated photonic switches, metasurface optics and tunable spectral filters. Nonetheless, modelling of PCM-based devices is challenging, both in terms of accurate representation of experimentally-derived material properties in different phase states, and standardization of results across the research community. In this work, we introduce PCMnet, an online database of the complex refractive indices of a variety of chalcogenide glass PCMs (such as GeSbTe), as an accessible and indexed repository for data sharing across the PCM community. Refractive indices (n) and extinction coefficients (k) between amorphous and crystalline states are directly extracted from experimentally-derived data in numerous academic research articles, and collated into the material resource database. Due to the inaccuracies associated with our data collection methods, this data is supplemented with additional computationally-generated data, obtained through WVASE, a commercial ellipsometry analysis software package. To demonstrate the utility of PCMnet, we provide a NASA application-driven device optimization example using the optical properties of PCMs collected with our database. We anticipate the database providing great use to the PCM community and coordinated research efforts enabled by PCMnet will promote the shared repository for the selection of appropriate PCMs for tunable nanophotonic device design for a range of applications., Comment: 19 pages, 8 figures, 1 table

Published

2021

22. Nonconventional metasurfaces: from non-Hermitian coupling, quantum interactions, to skin cloak

Author

Yuan Wang, Xuexin Ren, Pankaj K. Jha, and Xiang Zhang

Subjects

optical metasurface, cloaking, QC1-999, Cloaking, Physics::Optics, 02 engineering and technology, 01 natural sciences, Nanomaterials, Quantum mechanics, 0103 physical sciences, quantum vacuum engineering, Electrical and Electronic Engineering, 010306 general physics, Quantum, Coupling, Physics, Cloak, 021001 nanoscience & nanotechnology, Hermitian matrix, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, anti-hermitian, spin-hall effect, Spin Hall effect, 0210 nano-technology, Biotechnology

Abstract

Metasurfaces are optically thin layers of subwavelength resonators that locally tailor the electromagnetic response at the nanoscale. Our metasurface research aims at developing novel designs and applications of metasurfaces that go beyond the classical regimes. In contrast to conventional phase gradient metasurfaces where each meta-atom responds individually, we are interested in developing metasurfaces where neighboring meta-atoms are strongly coupled. By engineering a non-Hermitian coupling between the meta-atoms, new degrees of freedom are introduced and novel functionalities can be achieved. We are also interested in combining classical metasurface with quantum emitters, which may offer opportunities for on-chip quantum technologies. Additionally, we have been designing metasurfaces to realize exciting phenomena and applications, such as ultrathin metasurface cloak and strong photonic spin-Hall effect. In this paper, we review our research efforts in optical metasurfaces in the past few years, which ranges from conventional to novel type of metasurface and from classical to quantum regime.

Published

2018

23. Resonant Laser Printing of Optical Metasurfaces.

Author

Zhu X, Engelberg J, Remennik S, Zhou B, Pedersen JN, Uhd Jepsen P, Levy U, and Kristensen A

Abstract

One of the challenges for metasurface research is upscaling. The conventional methods for fabrication of metasurfaces, such as electron-beam or focused ion beam lithography, are not scalable. The use of ultraviolet steppers or nanoimprinting still requires large-size masks or stamps, which are costly and challenging in further handling. This work demonstrates a cost-effective and lithography-free method for printing optical metasurfaces. It is based on resonant absorption of laser light in an optical cavity formed by a multilayer structure of ultrathin metal and dielectric coatings. A nearly perfect light absorption is obtained via interferometric control of absorption and operating around a critical coupling condition. Controlled by the laser power, the surface undergoes a structural transition from random, semiperiodic, and periodic to amorphous patterns with nanoscale precision. The reliability, upscaling, and subwavelength resolution of this approach are demonstrated by realizing metasurfaces for structural colors, optical holograms, and diffractive optical elements.

Published

2022

24. Optical absorbers with NPs-based lossy metasurfaces

Author

Filiberto Bilotti, Alessandro Toscano, Alessio Monti, Andrea Alù, IEEE APS Organizing Committee, Monti, A, Alu, A, Toscano, A, and Bilotti, F

Subjects

optical metasurface, Salisbury screen, Plasmonic nanoparticles, Materials science, business.industry, Physics::Optics, 02 engineering and technology, 01 natural sciences, Light scattering, plasmonic nanoparticles, 010309 optics, 020210 optoelectronics & photonics, optical absorber, Color gel, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Optoelectronics, Color filter array, Optical filter, business, Electrical impedance, Nanoscopic scale, Visible spectrum

Abstract

In this contribution, we show how it is possible to exploit the exotic response of arrays of plasmonic nanoparticles (NPs) to design ultra-thin optical absorbers and color filters. First, it is shown that an array of electrically small spheroidal NPs may be effectively characterized using a complex-valued surface impedance tensor. Then, the model is exploited to design optical Salisbury-like screens able to absorb all the impinging light within a desired frequencies range. Finally, an innovative nanoscale color filter able to selectively absorb the light in a narrow frequencies band while being transparent in the rest of the IR and optical spectrum is proposed.

Published

2018

25. Circular to circular wide-band polarization conversion using GaAs layer.

Author

Dadkhahfard, Saeid

Abstract

Nowadays, planar structures are more common in the field of telecommunications in comparison with bulk metamaterial structure, not only for their lossless properties but also for their negligible dispersion coefficient. These two important features are available because of the metasurface thin layer and its small propagation length. In this paper, a novel metasurface is proposed with the application of circular to circular polarization conversion with at least 50% of polarization conversion ratio in a wavelength band from 1400 to 1700 nm. By using GaAs in the structure, our goal to have a tinier structure has been achieved because of its large refractive index. Also, the performance of our proposed work shows significant stability in the case of both theta and phi incident angles variations. By changing the incident wave angle from 0 to about 15 degrees (theta) and from 0 to 90 degree (phi) the stability of the conversion has been available. Finally, by using the PSO algorithm, the final optimized measures have been achieved. [ABSTRACT FROM AUTHOR]

Published

2021

26. Dynamic Beam Switching by Liquid Crystal Tunable Dielectric Metasurfaces

Author

Komar, Andrei, Paniagua-Domínguez, Ramón, Miroshnichenko, Andrey, Yu, Ye Feng, Kivshar, Yuri, Kuznetsov, Arseniy I., Neshev, Dragomir, Komar, Andrei, Paniagua-Domínguez, Ramón, Miroshnichenko, Andrey, Yu, Ye Feng, Kivshar, Yuri, Kuznetsov, Arseniy I., and Neshev, Dragomir

Abstract

Dynamic steering of laser beams by ultrathin optical metasurfaces is a significant research advance for possible applications in remote ranging and sensing. A unique platform for such important functionalities is offered by dielectric metasurfaces that have the highest transmission efficiency. However, the realization of dynamically tunable metasurfaces still remains a challenge. Here we experimentally demonstrate the dynamic switching of beam deflection by a silicon-nanodisk dielectric metasurface infiltrated with liquid crystals. In particular, we show the switching of a laser beam from 0° to a 12° angle with an efficiency of 50% by heating the metasurface to modify the liquid crystal state from nematic to isotropic. Our results open important opportunities for tunable ultrathin beam steering metadevices.

Published

2018

27. Metasurface Enhanced AFM Cantilevers

Author

Speet, B., Silvestri, F., Gerini, G., Mashaghi Tabari, S., Sadeghian, H., Boardman, Allan D., Zayats, Anatoly V., MacDonald, Kevin F., Electromagnetics, and Dynamics and Control

Subjects

Materials science, Cantilever, Polarization rotator, Industrial Innovation, Optical Metasurface, business.industry, Stray light, Detector, High Tech Systems & Materials, Polarization (waves), Ellipse, AFM probe, Atomic Force Microscopy, Resonator, Optics, Orthogonal coordinates, Electronics, business

Abstract

In this contribution, we present the application of an optical metasurface polarization rotator in an Atomic Force Microscopy (AFM) setup. In AFM, the laser beam used to measure the cantilever deflection is not entirely intercepted by the cantilever surface. Consequently, the remainder of the beam illuminates part of the surface under measurement. Part of the light scattered by the surface is intercepted by the Position Sensitive Detector (PSD), interfering with the measurement of the light that is directly reflected by the cantilever. This reduces the measurement Signal-to-Noise Ratio (SNR), decreasing the AFM accuracy and generating artefacts. To enhance the SNR we propose a metasurface reflective polarization rotator, directly integrated on the cantilever. The metasurface elliptical resonators, oriented at a certain angle with respect to the incoming polarization state, will induce different phase shifts on the two components parallel to the orthogonal axes of the ellipse. By properly tuning the dimensions of the resonators, a 90° rotation of the reflected light polarization with respect to the incident polarization is realized. We arrive at three designs with cross-polar reflectivities of 0.82, 0.86 and 0.66 and total reflectivities of 0.83, 0.87 and 0.68 correspondingly. The metasurface allows to discriminate the desired light, reflected by the cantilever, from stray light from the sample surface, which maintains mostly the original polarization. In this paper, performance of the different configurations will be presented and discussed together with other considerations relative to the mechanical performances of the enhanced cantilever.

Published

2018

28. Bifacial Metasurface with Quadrupole Optical Response

Author

Andriy Shevchenko, Ville Kivijärvi, Patrick Grahn, Matti Kaivola, Klas Lindfors, Department of Applied Physics, Aalto-yliopisto, and Aalto University

Subjects

optical metasurface, Materials science, ta221, General Physics and Astronomy, Physics::Optics, 02 engineering and technology, 01 natural sciences, 0103 physical sciences, 010306 general physics, Absorption (electromagnetic radiation), Nanoscopic scale, electromagnetic multipoles, ta218, ta214, ta114, business.industry, Detector, Metamaterial, 021001 nanoscience & nanotechnology, asymmetric reflectivity, Optical reflection, Interferometry, Quadrupole, Optoelectronics, 0210 nano-technology, business, Visible spectrum

Abstract

We design, fabricate, and characterize a metasurface, whose multipole optical response depends significantly on the illumination direction. The metasurface is composed of gold-nanodisc dimers embedded in glass. In spite of their nanoscale size, the dimers exhibit a dominating electric-current-quadrupole response in a wide range of wavelengths around 700 nm when illuminated from one side, and a primarily electric-dipole response when illuminated from the opposite side. This leads to two consequences. First, the reflection coefficient of the metasurface considerably differs for the two sides of illumination. Second, quadrupole excitation results in a significant local enhancement of both electric and magnetic fields around the dimers. Our experimental spectroscopic data are in good agreement with simulations obtained using a multipole expansion model.

Published

2015

29. Stimuli-Responsive DNA-Linked Nanoparticle Arrays as Programmable Surfaces.

Author

Myers BD, Palacios E, Myers DI, Butun S, Aydin K, and Dravid VP

Subjects

DNA chemistry, Gold chemistry, Metal Nanoparticles chemistry, Nanotubes chemistry

Abstract

Self- and directed-assembly approaches have enabled precise control over the composition and geometry of 2D and 3D nanoparticle constructs. However, the resulting structures are typically static, providing only a single structural arrangement of the nanoparticle building blocks. In this work, the power of DNA-linked nanoparticle assembly is coupled to a grayscale patterning technique to create programmable surfaces for assembly and thermally activated reorganization of gold nanoparticle arrays. Direct grayscale patterning of DNA monolayers by electron-beam lithography (DNA-EBL) enables the production of surfaces with nanometer-scale control over the density of functional DNA. This enables tuning of the particle-surface interactions with single-nanoparticle resolution and without the need for a physical template as employed in most directed assembly methods. This technique is applied on suspended membrane structures to achieve high-resolution assembly of 2D nanoparticle arrays with highly mutable architectures. Gold nanorods assembled on grayscale-patterned surfaces exhibit temperature-dependent configurations and ordering behavior that result in tunable polarization-dependent optical properties. In addition, spherical gold particles assembled from a bimodal suspension produce arrays with temperature-dependent configurations of small and large particles. These results have important implications for the design and fabrication of reconfigurable nanoparticle arrays for application as structurally tunable optical metasurfaces.

Published

2019

30. Two-Photon Microscopy with a Double-Wavelength Metasurface Objective Lens.

Author

Arbabi E, Li J, Hutchins RJ, Kamali SM, Arbabi A, Horie Y, Van Dorpe P, Gradinaru V, Wagenaar DA, and Faraon A

Abstract

Two-photon microscopy is a key imaging technique in life sciences due to its superior deep-tissue imaging capabilities. Light-weight and compact two-photon microscopes are of great interest because of their applications for in vivo deep brain imaging. Recently, dielectric metasurfaces have enabled a new category of small and lightweight optical elements, including objective lenses. Here we experimentally demonstrate two-photon microscopy using a double-wavelength metasurface lens. It is specifically designed to focus 820 and 605 nm light, corresponding to the excitation and emission wavelengths of the measured fluorophors, to the same focal distance. The captured two-photon images are qualitatively comparable to the ones taken by a conventional objective lens. Our metasurface lens can enable ultracompact two-photon microscopes with similar performance compared to current systems that are usually based on graded-index-lenses. In addition, further development of tunable metasurface lenses will enable fast axial scanning for volumetric imaging.

Published

2018

31. Měření lokální fáze metapovrchů pomocí digitální holografické mikroskopie

Author

Dvořák, Petr, Bouchal, Petr, Weiss, Vlastimil, Dvořák, Petr, Bouchal, Petr, and Weiss, Vlastimil

Abstract

Tato bakalářská práce se zabývá rešeršní studií optických metapovrchů, které dokáží modifikovat a ovládat dopadající záření díky změně lokální fáze. Dále pojednává o experimentálních mikroskopických technikách, které dokáží měřit rozložení této fáze. Tato práce prezentuje experimentální výsledky distribuce fáze elektromagnetické vlny dopadající na kovový metapovrch, které jsou získané pomocí kvantitativní jednosvazkové i mimoosé digitální holografické mikroskopie. Jedná se o metapovrchy na principu jak změny geometrické fáze, tak i lokalizované povrchové plazmonové rezonance (LSPR). Naměřené výsledky jsou v souladu s vybudovaným teoretickým základem. K závěru jsou pak prezentována úspěšná měření geometrické fáze od individuálních stavebních bloků a aplikace analytického modelu pro popis fázové odezvy metapovrchů., This bachelor's thesis consists of research studies of optical metasurfaces that are capable of modifying and governing incident radiation via the shift of a local phase. It also discusses experimental microscopic techniques with the ability to measure the distribution of the said phase. Experimental results of the phase distribution of the electromagnetic wave impinging on metal metasurface presented in this thesis are captured through quantitative in-line and off-axis digital holographic microscopy. These metasurfaces utilize both geometrical phase and localised surface plasmon resonance (LSPR). Measured results are in accordance with previous scientific studies. Finally, the successful outcome in the form of measurement of the geometrical phase introduced by the single building block is presented as well as the application of an analytical model for characterization of phase response generated by interaction with optical metasurfaces.

32. Měření lokální fáze metapovrchů pomocí digitální holografické mikroskopie

Author

Dvořák, Petr, Bouchal, Petr, Weiss, Vlastimil, Dvořák, Petr, Bouchal, Petr, and Weiss, Vlastimil

Abstract

Tato bakalářská práce se zabývá rešeršní studií optických metapovrchů, které dokáží modifikovat a ovládat dopadající záření díky změně lokální fáze. Dále pojednává o experimentálních mikroskopických technikách, které dokáží měřit rozložení této fáze. Tato práce prezentuje experimentální výsledky distribuce fáze elektromagnetické vlny dopadající na kovový metapovrch, které jsou získané pomocí kvantitativní jednosvazkové i mimoosé digitální holografické mikroskopie. Jedná se o metapovrchy na principu jak změny geometrické fáze, tak i lokalizované povrchové plazmonové rezonance (LSPR). Naměřené výsledky jsou v souladu s vybudovaným teoretickým základem. K závěru jsou pak prezentována úspěšná měření geometrické fáze od individuálních stavebních bloků a aplikace analytického modelu pro popis fázové odezvy metapovrchů., This bachelor's thesis consists of research studies of optical metasurfaces that are capable of modifying and governing incident radiation via the shift of a local phase. It also discusses experimental microscopic techniques with the ability to measure the distribution of the said phase. Experimental results of the phase distribution of the electromagnetic wave impinging on metal metasurface presented in this thesis are captured through quantitative in-line and off-axis digital holographic microscopy. These metasurfaces utilize both geometrical phase and localised surface plasmon resonance (LSPR). Measured results are in accordance with previous scientific studies. Finally, the successful outcome in the form of measurement of the geometrical phase introduced by the single building block is presented as well as the application of an analytical model for characterization of phase response generated by interaction with optical metasurfaces.

33. Výroba SiC optických metapovrchů

Author

Dvořák, Petr, Idesová, Beáta, Štálnik, Jozef, Dvořák, Petr, Idesová, Beáta, and Štálnik, Jozef

Abstract

Cieľom tejto bakalárske práce bolo optimalizovať výrobný proces SiC metapovrchov, ktoré sa prejavili ako revolučná náhrada klasických optických prvkov, kvôli ich vlastnosti ovládať dopadajúce svetlo vďaka lokálnej fázovej zmene. Ďalej pojednáva o využití karbidu kremíku v ako paltformy pre tieto fotonické zariadenia a experimentálne techniky využité v samotnom procese tvorby metapovrchu. V experimentálne časti sa prezentujú výsledky výroby silikon karbidových nanoštruktúr, kedy hlavným krokom optimalizácie bolo suché leptanie plazmou. Nakonci sa prezentovali optické merania fázového profilu výsledných metapovrchov pomocou mimoosej digitálnej holografie. Hlavným výsledkom tejto práce je vytvorenie knižnice individuálnych stavebných blokov, ktoré budú dôležité budúcej aplikácií., The aim of this bachelor's thesis was to optimize the manufacturing process of SiC meta-surfaces, which have emerged as a revolutionary replacement for classical optical elements due to their ability to control incident light through local phase modulation. Furthermore, it discusses the utilization of silicon carbide as a platform for these photonic devices and the experimental techniques employed in the meta-surface fabrication process. The experimental section presents the results of silicon carbide nanostructure fabrication, with dry plasma etching being the key optimization step. Finally, optical measurements of the phase profile of the resulting meta-surfaces are presented using off-axis digital holography. The main outcome of this work is the creation of a library of individual building blocks crucial for future applications.

34. Výroba SiC optických metapovrchů

Author

Dvořák, Petr, Idesová, Beáta, Štálnik, Jozef, Dvořák, Petr, Idesová, Beáta, and Štálnik, Jozef

Abstract

Cieľom tejto bakalárske práce bolo optimalizovať výrobný proces SiC metapovrchov, ktoré sa prejavili ako revolučná náhrada klasických optických prvkov, kvôli ich vlastnosti ovládať dopadajúce svetlo vďaka lokálnej fázovej zmene. Ďalej pojednáva o využití karbidu kremíku v ako paltformy pre tieto fotonické zariadenia a experimentálne techniky využité v samotnom procese tvorby metapovrchu. V experimentálne časti sa prezentujú výsledky výroby silikon karbidových nanoštruktúr, kedy hlavným krokom optimalizácie bolo suché leptanie plazmou. Nakonci sa prezentovali optické merania fázového profilu výsledných metapovrchov pomocou mimoosej digitálnej holografie. Hlavným výsledkom tejto práce je vytvorenie knižnice individuálnych stavebných blokov, ktoré budú dôležité budúcej aplikácií., The aim of this bachelor's thesis was to optimize the manufacturing process of SiC meta-surfaces, which have emerged as a revolutionary replacement for classical optical elements due to their ability to control incident light through local phase modulation. Furthermore, it discusses the utilization of silicon carbide as a platform for these photonic devices and the experimental techniques employed in the meta-surface fabrication process. The experimental section presents the results of silicon carbide nanostructure fabrication, with dry plasma etching being the key optimization step. Finally, optical measurements of the phase profile of the resulting meta-surfaces are presented using off-axis digital holography. The main outcome of this work is the creation of a library of individual building blocks crucial for future applications.

35. Měření lokální fáze metapovrchů pomocí digitální holografické mikroskopie

Author

Dvořák, Petr, Bouchal, Petr, Dvořák, Petr, and Bouchal, Petr

Abstract

Tato bakalářská práce se zabývá rešeršní studií optických metapovrchů, které dokáží modifikovat a ovládat dopadající záření díky změně lokální fáze. Dále pojednává o experimentálních mikroskopických technikách, které dokáží měřit rozložení této fáze. Tato práce prezentuje experimentální výsledky distribuce fáze elektromagnetické vlny dopadající na kovový metapovrch, které jsou získané pomocí kvantitativní jednosvazkové i mimoosé digitální holografické mikroskopie. Jedná se o metapovrchy na principu jak změny geometrické fáze, tak i lokalizované povrchové plazmonové rezonance (LSPR). Naměřené výsledky jsou v souladu s vybudovaným teoretickým základem. K závěru jsou pak prezentována úspěšná měření geometrické fáze od individuálních stavebních bloků a aplikace analytického modelu pro popis fázové odezvy metapovrchů., This bachelor's thesis consists of research studies of optical metasurfaces that are capable of modifying and governing incident radiation via the shift of a local phase. It also discusses experimental microscopic techniques with the ability to measure the distribution of the said phase. Experimental results of the phase distribution of the electromagnetic wave impinging on metal metasurface presented in this thesis are captured through quantitative in-line and off-axis digital holographic microscopy. These metasurfaces utilize both geometrical phase and localised surface plasmon resonance (LSPR). Measured results are in accordance with previous scientific studies. Finally, the successful outcome in the form of measurement of the geometrical phase introduced by the single building block is presented as well as the application of an analytical model for characterization of phase response generated by interaction with optical metasurfaces.

36. Měření lokální fáze metapovrchů pomocí digitální holografické mikroskopie

Author

Dvořák, Petr, Bouchal, Petr, Dvořák, Petr, and Bouchal, Petr

Abstract

Tato bakalářská práce se zabývá rešeršní studií optických metapovrchů, které dokáží modifikovat a ovládat dopadající záření díky změně lokální fáze. Dále pojednává o experimentálních mikroskopických technikách, které dokáží měřit rozložení této fáze. Tato práce prezentuje experimentální výsledky distribuce fáze elektromagnetické vlny dopadající na kovový metapovrch, které jsou získané pomocí kvantitativní jednosvazkové i mimoosé digitální holografické mikroskopie. Jedná se o metapovrchy na principu jak změny geometrické fáze, tak i lokalizované povrchové plazmonové rezonance (LSPR). Naměřené výsledky jsou v souladu s vybudovaným teoretickým základem. K závěru jsou pak prezentována úspěšná měření geometrické fáze od individuálních stavebních bloků a aplikace analytického modelu pro popis fázové odezvy metapovrchů., This bachelor's thesis consists of research studies of optical metasurfaces that are capable of modifying and governing incident radiation via the shift of a local phase. It also discusses experimental microscopic techniques with the ability to measure the distribution of the said phase. Experimental results of the phase distribution of the electromagnetic wave impinging on metal metasurface presented in this thesis are captured through quantitative in-line and off-axis digital holographic microscopy. These metasurfaces utilize both geometrical phase and localised surface plasmon resonance (LSPR). Measured results are in accordance with previous scientific studies. Finally, the successful outcome in the form of measurement of the geometrical phase introduced by the single building block is presented as well as the application of an analytical model for characterization of phase response generated by interaction with optical metasurfaces.

37. Měření lokální fáze metapovrchů pomocí digitální holografické mikroskopie

Author

Dvořák, Petr, Bouchal, Petr, Dvořák, Petr, and Bouchal, Petr

Abstract

Tato bakalářská práce se zabývá rešeršní studií optických metapovrchů, které dokáží modifikovat a ovládat dopadající záření díky změně lokální fáze. Dále pojednává o experimentálních mikroskopických technikách, které dokáží měřit rozložení této fáze. Tato práce prezentuje experimentální výsledky distribuce fáze elektromagnetické vlny dopadající na kovový metapovrch, které jsou získané pomocí kvantitativní jednosvazkové i mimoosé digitální holografické mikroskopie. Jedná se o metapovrchy na principu jak změny geometrické fáze, tak i lokalizované povrchové plazmonové rezonance (LSPR). Naměřené výsledky jsou v souladu s vybudovaným teoretickým základem. K závěru jsou pak prezentována úspěšná měření geometrické fáze od individuálních stavebních bloků a aplikace analytického modelu pro popis fázové odezvy metapovrchů., This bachelor's thesis consists of research studies of optical metasurfaces that are capable of modifying and governing incident radiation via the shift of a local phase. It also discusses experimental microscopic techniques with the ability to measure the distribution of the said phase. Experimental results of the phase distribution of the electromagnetic wave impinging on metal metasurface presented in this thesis are captured through quantitative in-line and off-axis digital holographic microscopy. These metasurfaces utilize both geometrical phase and localised surface plasmon resonance (LSPR). Measured results are in accordance with previous scientific studies. Finally, the successful outcome in the form of measurement of the geometrical phase introduced by the single building block is presented as well as the application of an analytical model for characterization of phase response generated by interaction with optical metasurfaces.

38. Měření lokální fáze metapovrchů pomocí digitální holografické mikroskopie

Author

Dvořák, Petr, Bouchal, Petr, Weiss, Vlastimil, Dvořák, Petr, Bouchal, Petr, and Weiss, Vlastimil

Abstract

Tato bakalářská práce se zabývá rešeršní studií optických metapovrchů, které dokáží modifikovat a ovládat dopadající záření díky změně lokální fáze. Dále pojednává o experimentálních mikroskopických technikách, které dokáží měřit rozložení této fáze. Tato práce prezentuje experimentální výsledky distribuce fáze elektromagnetické vlny dopadající na kovový metapovrch, které jsou získané pomocí kvantitativní jednosvazkové i mimoosé digitální holografické mikroskopie. Jedná se o metapovrchy na principu jak změny geometrické fáze, tak i lokalizované povrchové plazmonové rezonance (LSPR). Naměřené výsledky jsou v souladu s vybudovaným teoretickým základem. K závěru jsou pak prezentována úspěšná měření geometrické fáze od individuálních stavebních bloků a aplikace analytického modelu pro popis fázové odezvy metapovrchů., This bachelor's thesis consists of research studies of optical metasurfaces that are capable of modifying and governing incident radiation via the shift of a local phase. It also discusses experimental microscopic techniques with the ability to measure the distribution of the said phase. Experimental results of the phase distribution of the electromagnetic wave impinging on metal metasurface presented in this thesis are captured through quantitative in-line and off-axis digital holographic microscopy. These metasurfaces utilize both geometrical phase and localised surface plasmon resonance (LSPR). Measured results are in accordance with previous scientific studies. Finally, the successful outcome in the form of measurement of the geometrical phase introduced by the single building block is presented as well as the application of an analytical model for characterization of phase response generated by interaction with optical metasurfaces.