Varifocal Metalens for Optical Sectioning Fluorescence Microscopy

Luo, Yuan; Chu, Cheng Hung; Vyas, Sunil; Kuo, Hsin Yu; Chia, Yu Hsin; Chen, Mu Ku; Shi, Xu; Tanaka, Takuo; Misawa, Hiroaki; Huang, Yi You; Tsai, Din Ping

doi:10.1021/acs.nanolett.1c01114

Cited by 107 publications

(51 citation statements)

References 50 publications

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Section: Progress and Challenges For Typical Performancesmentioning

confidence: 99%

“…The performance of metalenses is degraded by a series of fabrication imperfections. For the sake of high resolution, most metalenses especially those operating in the visible regime have been fabricated by electron-beam lithography (EBL) or focused ion beam (FIB) techniques 201 (including those with millimeter-diameter 35 , 41 , 47 , 65 , 66 , 70 , 71 , 89 , 122 , 128 , 130 , 163 , 202 ). Nevertheless, a typical EBL or FIB process to define large area structures suffers from time-consuming and high costs.…”

Section: Common Challenges For Further Developmentmentioning

confidence: 99%

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Dielectric metalens for miniaturized imaging systems: progress and challenges

et al. 2022

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Lightweight, miniaturized optical imaging systems are vastly anticipated in these fields of aerospace exploration, industrial vision, consumer electronics, and medical imaging. However, conventional optical techniques are intricate to downscale as refractive lenses mostly rely on phase accumulation. Metalens, composed of subwavelength nanostructures that locally control light waves, offers a disruptive path for small-scale imaging systems. Recent advances in the design and nanofabrication of dielectric metalenses have led to some high-performance practical optical systems. This review outlines the exciting developments in the aforementioned area whilst highlighting the challenges of using dielectric metalenses to replace conventional optics in miniature optical systems. After a brief introduction to the fundamental physics of dielectric metalenses, the progress and challenges in terms of the typical performances are introduced. The supplementary discussion on the common challenges hindering further development is also presented, including the limitations of the conventional design methods, difficulties in scaling up, and device integration. Furthermore, the potential approaches to address the existing challenges are also deliberated.

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Section: Progress and Challenges For Typical Performancesmentioning

confidence: 99%

Section: Common Challenges For Further Developmentmentioning

confidence: 99%

Dielectric metalens for miniaturized imaging systems: progress and challenges

et al. 2022

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“…Moreover, our metasurface based on beam shaper can be directly integrated with fiber optic probes and microfluidic devices [ 60 , 62 ]. Moreover, a tunable metasurface based on beam shaper can be designed to adjust trapping potentials along the axial direction [ 63 , 64 , 65 ]. Our technique is not limited only to Airy beams, and other exotic light beams can be created from a metasurface with different operation wavelengths, without any additional optical components.…”

Section: Discussionmentioning

confidence: 99%

Cubic-Phase Metasurface for Three-Dimensional Optical Manipulation

et al. 2021

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The optical tweezer is one of the important techniques for contactless manipulation in biological research to control the motion of tiny objects. For three-dimensional (3D) optical manipulation, shaped light beams have been widely used. Typically, spatial light modulators are used for shaping light fields. However, they suffer from bulky size, narrow operational bandwidth, and limitations of incident polarization states. Here, a cubic-phase dielectric metasurface, composed of GaN circular nanopillars, is designed and fabricated to generate a polarization-independent vertically accelerated two-dimensional (2D) Airy beam in the visible region. The distinctive propagation characteristics of a vertically accelerated 2D Airy beam, including non-diffraction, self-acceleration, and self-healing, are experimentally demonstrated. An optical manipulation system equipped with a cubic-phase metasurface is designed to perform 3D manipulation of microscale particles. Due to the high-intensity gradients and the reciprocal propagation trajectory of Airy beams, particles can be laterally shifted and guided along the axial direction. In addition, the performance of optical trapping is quantitatively evaluated by experimentally measured trapping stiffness. Our metasurface has great potential to shape light for compact systems in the field of physics and biological applications.

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“…Integrated multilayer metasurface layouts have often been used to achieve kaleidoscopic wavefront control, [38] multispectral achromatic metalenses, [39] image differentiation, [40] Janus metasurfaces with bidirectional functionality, [41][42][43] holography with asymmetric transmission, [44] holography with color printing, [45] and all-optical machine learning frameworks. [46] For cascaded metasurfaces, whose components can be replaced, translated, or rotated, impressive functionalities such as prescribing light trajectories, [47] Moiré metalens for adjustable focal length, [48] dynamical wavefront modulators, [49] etc., have been demonstrated. Furthermore, the cascaded holography method allows for physical separation and combination of encoded information.…”

Section: Introductionmentioning

confidence: 99%

Rotational Multiplexing Method Based on Cascaded Metasurface Holography

Wei

Huang

Zhao

et al. 2022

Advanced Optical Materials

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Since the emergence of optical metasurfaces, their outstanding wavefront modulation ability and numerous degrees of freedom (DOFs) have motivated many multiplexing methods, and many unprecedented functionalities and impressive advances have been achieved. However, the number of DOFs of single‐layer metasurfaces is intrinsically limited. To further explore the innovative multiplexing dimensions and application scenarios of metasurfaces, multilayer and cascaded metasurfaces are proposed. Inspired by the alignment sensitivity of cascaded metasurface holography, here the authors use the in‐plane rotation between two cascaded metasurfaces as an additional design DOF to introduce the concept of the rotational multiplexing method. An iterative gradient optimization scheme based on a machine learning method is developed to obtain the phase profiles. Dual working modes can be achieved, and both single‐layer and rotational cascaded holography can be reconstructed in the far‐field. Such versatile configurations may provide promising solutions for optical encryption, data storage, and dynamic display.

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Varifocal Metalens for Optical Sectioning Fluorescence Microscopy

Cited by 107 publications

References 50 publications

Dielectric metalens for miniaturized imaging systems: progress and challenges

Dielectric metalens for miniaturized imaging systems: progress and challenges

Cubic-Phase Metasurface for Three-Dimensional Optical Manipulation

Rotational Multiplexing Method Based on Cascaded Metasurface Holography

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