Generation and Manipulation of Superoscillatory Hotspots Using Virtual Fourier Filtering and CTF Shaping

Biomedical and metasurface researchers repeatedly reach for quantitative phase imaging (QPI) as their primary imaging technique due to its high-throughput, label-free, quantitative nature. So far, very little progress has been made towards achieving super-resolution in QPI. However, the possible super-resolving QPI would satisfy the need for quantitative observation of previously unresolved biological specimen features and allow unprecedented throughputs in the imaging of dielectric metasurfaces. Here we present a method capable of real-time super-resolution QPI, which we achieve by shaping the coherence gate in the holographic microscope with partially coherent illumination. Our approach is based on the fact that the point spread function (PSF) of such a system is a product of the diffraction-limited spot and the coherence-gating function (CGF) shaped similarly to the superoscillatory hotspot. The product simultaneously produces the PSF with a super-resolution central peak and minimizes sidelobe effects commonly devaluating the superoscillatory imaging. The minimization of sidelobes and resolution improvement co-occur in the entire field of view. Therefore, for the first time we achieve a single-shot widefield super-resolution QPI. We demonstrate here resolution improvement on simulated as well as experimental data. A phase resolution target imaging shows a resolving power improvement of 19%. Finally, we show the practical feasibility by applying the proposed method to the imaging of biological specimens.

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Single-shot super-resolution quantitative phase imaging allowed by coherence gate shaping

Ďuriš

Bouchal

Chmelík

2023

APL Photonics

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Phase-only mask for superoscillatory enhanced resolution in confocal microscopy

Iglesias,

Filiu

2024

Opt. Express

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In this work, we present a simple phase mask that generates a superoscillatory spot suitable for confocal scanning microscopy enabling lateral sub-diffraction resolution. When considering linearly polarized light, the mask enhances the resolving power along the axis perpendicular to the polarization direction. The symmetry of the enhancement is recovered if the mask is combined with radial polarization.

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Generation and Manipulation of Superoscillatory Hotspots Using Virtual Fourier Filtering and CTF Shaping

Cited by 2 publications

References 32 publications

Single-shot super-resolution quantitative phase imaging allowed by coherence gate shaping

Single-shot super-resolution quantitative phase imaging allowed by coherence gate shaping

Phase-only mask for superoscillatory enhanced resolution in confocal microscopy

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