Establishing a library of metasurface building blocks through coherence-controlled holographic microscopy

Establishing a library of metasurface building blocks through coherence-controlled holographic microscopy

Článek WoS

Digital holographic microscopy is a powerful tool for characterizing transparent and reflective phase objects. Its ability to reconstruct amplitude and phase can also offer great insight into wavefront shaping and design of all-dielectric optical metasurfaces. While metasurfaces have reached widespread popularity, their design is often based purely on the results of numerical simulations, which can overlook many of the real-world fabrication imperfections. Being able to verify the real phase response of a fabricated device is of great utility for high-performance devices. Here, we use holographic microscopy to validate metalibraries of rectangular TiO2 and Si building blocks. Illumination effects are studied for wavelengths from 600 to 740 nm and linear polarization rotating within the full range of unique states (0 degrees-180 degrees). Finally, by varying the numerical aperture of the condenser lens from 0.05 to 0.5, we also study the effects of an off-axis illumination. Comparing the experimental results with simulations from finite-difference time-domain and rigorous coupled-wave analysis, we highlight the limitations of these theoretical predictions and underscore the utility of an experimentally established library of building blocks. We demonstrate that our proposed method of holographic microscopy is both practical and effective for creating a metalibrary that accounts for all fabrication and material imperfections, which is crucial for designing high-efficiency metasurfaces.

Digital holographic microscopy is a powerful tool for characterizing transparent and reflective phase objects. Its ability to reconstruct amplitude and phase can also offer great insight into wavefront shaping and design of all-dielectric optical metasurfaces. While metasurfaces have reached widespread popularity, their design is often based purely on the results of numerical simulations, which can overlook many of the real-world fabrication imperfections. Being able to verify the real phase response of a fabricated device is of great utility for high-performance devices. Here, we use holographic microscopy to validate metalibraries of rectangular TiO2 and Si building blocks. Illumination effects are studied for wavelengths from 600 to 740 nm and linear polarization rotating within the full range of unique states (0 degrees-180 degrees). Finally, by varying the numerical aperture of the condenser lens from 0.05 to 0.5, we also study the effects of an off-axis illumination. Comparing the experimental results with simulations from finite-difference time-domain and rigorous coupled-wave analysis, we highlight the limitations of these theoretical predictions and underscore the utility of an experimentally established library of building blocks. We demonstrate that our proposed method of holographic microscopy is both practical and effective for creating a metalibrary that accounts for all fabrication and material imperfections, which is crucial for designing high-efficiency metasurfaces.

DIELECTRIC METASURFACES; PLASMONIC NANOANTENNAS; FLAT OPTICS; PHASE; POLARIZATION; RESOLUTION

DIELECTRIC METASURFACES; PLASMONIC NANOANTENNAS; FLAT OPTICS; PHASE; POLARIZATION; RESOLUTION

ČERVINKA, O.; WEISS, V.; HRTOŇ, M.; BOUCHAL, P.; LIŠKA, P.; LIGMAJER, F.; ŠIKOLA, T.; VIEWEGH, P.

07.02.2026

Journal of applied physics

139

5

Spojené státy americké

11

https://pubs.aip.org/aip/jap/article/139/5/053103/3378719/Establishing-a-library-of-metasurface-building