Model-based optical proximity correction for immersion lithography-based flat optics platform

Choi, Narak; Lai, Keng Heng; Sundaram, Arvind; Singh, Navab; Fu, Yuan Hsing; Lee, Lennon Y. T.

doi:10.1117/12.2647686

Cited by 2 publications

References 11 publications

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Investigating pathways for deep-UV photolithography of large-area nanopost-based metasurfaces with high feature-size contrast

Palatnick,

John,

Millar-Blanchaer

2024

Journal of Vacuum Science &Amp; Technology B

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A major challenge in photolithography-based nanofabrication is the patterning of large features next to small features. However, such arrangements of features are often required by nanofabricated devices such as metasurfaces. Oftentimes, electron-beam lithography is utilized to circumvent this problem, but at the expense of cost, fabrication time, and limited write-area, which, thus, limits fabrication throughput. In this work, we detail an aperiodic design framework for metasurfaces that can achieve 2π phase control in the near-infrared (NIR) and can be easily fabricated with deep-UV photolithography. We also explore several approaches by which we can achieve the fabrication of fixed pitch metasurfaces with a range of nanopost diameters as small as 220 nm and as large as 480 nm directly adjacent to one another by splitting each device into several photomask images based on a nanopost diameter and/or a pitch, a diluting photoresist developer, and tailoring photoresist thickness. We report on the effectiveness of each strategy individually and in combination with each other and characterize the optical behavior of metasurfaces fabricated with these techniques. Ultimately, we find that using a combination of all three strategies results in the best fabrication performance, allowing us to fabricate 1 mm2 NIR metasurfaces that can achieve 2π phase control within design tolerance specifications and can be scaled to large-area optics.

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Investigating pathways for deep-UV photolithography of large-area nanopost-based metasurfaces with high feature-size contrast

Palatnick,

John,

Millar-Blanchaer

2024

Journal of Vacuum Science &Amp; Technology B

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High efficiency metalens design using wavefront error optimization

Choi,

Lai,

2024

High Contrast Metastructures XIII

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Conventional metalens design is based on the library where phases and transmissions of the meta-atoms are calculated with the periodic boundary condition. And the most suitable meta-atom is picked up from the library ignoring its environment. However, the coupling between adjacent meta-atoms produces the phase error, leading to low efficiency and scattering of the metalens. We proposed a method of numerical optimization of the wavefront error by adjusting the meta-atoms size, which reduces phase errors leading to higher efficiency compared to the conventional metalens design. This method is scalable for a large size metalens and for metalens with an arbitrary phase profile.

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Model-based optical proximity correction for immersion lithography-based flat optics platform

Cited by 2 publications

References 11 publications

Investigating pathways for deep-UV photolithography of large-area nanopost-based metasurfaces with high feature-size contrast

Investigating pathways for deep-UV photolithography of large-area nanopost-based metasurfaces with high feature-size contrast

High efficiency metalens design using wavefront error optimization

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