Dielectric Metalens by Multilayer Nanoimprint Lithography and Solution Phase Epitaxy

Quan, Dunhang; Li, Xuan; Tang, Yi; Liu, Hongjun; Min, Siyi; Li, Guixin; Srivastava, Abhishek Kumar; Cheng, Xing

doi:10.1002/adem.202201824

Cited by 3 publications

(2 citation statements)

References 37 publications

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“…The inset images on the right showcase SEM images of the ZnO metalens. [283] Fig. 14 The utilization of self-assembly in the fabrication of all-dielectric metasurfaces.…”

Section: Extreme Fabrication and Applicationmentioning

confidence: 99%

“…This method, unlike conventional NIL, avoids introducing shear stress in cured nanostructures, enabling the replication of various patterns without faults. Moreover, through the utilization of multilayer NIL and solution-phase epitaxy (SPE), high-aspect-ratio ZnO nanopillar-based metalenses are successfully demonstrated [283] . The main procedure, as illustrated in Fig.…”

Section: Nanofabrication Techniques Of All-dielectric Metasurfacesmentioning

confidence: 99%

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Advanced manufacturing of dielectric meta-devices

Yang,

Zhou,

Tsai

et al. 2024

Photonics Insights

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Metasurfaces, composed of two-dimensional nanostructures, exhibit remarkable capabilities in shaping wavefronts, encompassing phase, amplitude, and polarization. This unique proficiency heralds a transformative paradigm shift in the domain of next-generation optics and photonics, culminating in the development of flat and ultrathin optical devices. Particularly noteworthy is the all-dielectric-based metasurface, leveraging materials such as titanium dioxide, silicon, gallium arsenide, and silicon nitride, which finds extensive application in the design and implementation of high-performance optical devices, owing to its notable advantages, including a high refractive index, low ohmic loss, and cost-effectiveness. Furthermore, the remarkable growth in nanofabrication technologies allows for the exploration of new methods in metasurface fabrication, especially through wafer-scale nanofabrication technologies, thereby facilitating the realization of commercial applications for metasurfaces. This review provides a comprehensive overview of the latest advancements in state-of-the-art fabrication technologies in dielectric metasurface areas. These technologies, including standard nanolithography [e.g., electron beam lithography (EBL) and focused ion beam (FIB) lithography], advanced nanolithography (e.g., grayscale and scanning probe lithography), and large-scale nanolithography [e.g., nanoimprint and deep ultraviolet (DUV) lithography], are utilized to fabricate highresolution, high-aspect-ratio, flexible, multilayer, slanted, and wafer-scale all-dielectric metasurfaces with intricate nanostructures. Ultimately, we conclude with a perspective on current cutting-edge nanofabrication technologies.

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“…The inset images on the right showcase SEM images of the ZnO metalens. [283] Fig. 14 The utilization of self-assembly in the fabrication of all-dielectric metasurfaces.…”

Section: Extreme Fabrication and Applicationmentioning

confidence: 99%

Section: Nanofabrication Techniques Of All-dielectric Metasurfacesmentioning

confidence: 99%

Advanced manufacturing of dielectric meta-devices

Yang,

Zhou,

Tsai

et al. 2024

Photonics Insights

View full text Add to dashboard Cite

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A Review on Reconfigurable Metalenses Revolutionizing Flat Optics

Khonina,

Butt,

Kazanskiy

2023

Advanced Optical Materials

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Metalenses (MLs), representing a groundbreaking paradigm shift within the realm of optics, have ushered in a transformative era in the ability to manipulate and harness the power of light. Diverging from the conventional approach reliant on curved surfaces to bend light, MLs harness intricate arrays of minuscule nanostructures to exert precise control over the phase and amplitude of incident light waves. This revolutionary technology bestows a plethora of advantages, including the creation of ultra‐compact optical systems, the enhancement of focusing capabilities to unprecedented levels, and the capability to rectify optical aberrations in a significantly thinner and more lightweight form factor. MLs have discovered a multitude of applications spanning diverse fields, from imaging and photography to augmenting reality and refining medical devices. They stand as a beacon of hope for reshaping the landscape of optical systems, courtesy of their remarkable adaptability and exceptional performance. As the evolution of MLs forges ahead, they hold immense potential to transcend the boundaries of what can be accomplished in the domain of light‐based technologies. This review presents the recent advances in reconfigurable MLs and their applicability to imaging systems.

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Revolutionary Integration of Artificial Intelligence with Meta-Optics-Focus on Metalenses for Imaging

Kazanskiy,

Khonina,

Oseledets

et al. 2024

Technologies

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Artificial intelligence (AI) significantly enhances the development of Meta-Optics (MOs), which encompasses advanced optical components like metalenses and metasurfaces designed to manipulate light at the nanoscale. The intricate design of these components requires sophisticated modeling and optimization to achieve precise control over light behavior, tasks for which AI is exceptionally well-suited. Machine learning (ML) algorithms can analyze extensive datasets and simulate numerous design variations to identify the most effective configurations, drastically speeding up the development process. AI also enables adaptive MOs that can dynamically adjust to changing imaging conditions, improving performance in real-time. This results in superior image quality, higher resolution, and new functionalities across various applications, including microscopy, medical diagnostics, and consumer electronics. The combination of AI with MOs thus epitomizes a transformative advancement, pushing the boundaries of what is possible in imaging technology. In this review, we explored the latest advancements in AI-powered metalenses for imaging applications.

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Dielectric Metalens by Multilayer Nanoimprint Lithography and Solution Phase Epitaxy

Cited by 3 publications

References 37 publications

Advanced manufacturing of dielectric meta-devices

Advanced manufacturing of dielectric meta-devices

A Review on Reconfigurable Metalenses Revolutionizing Flat Optics

Revolutionary Integration of Artificial Intelligence with Meta-Optics-Focus on Metalenses for Imaging

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