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Main Authors: Roy, Tamal, Brown, Peter T., Shepherd, Douglas P., Poulikakos, Lisa V.
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2309.14456
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author Roy, Tamal
Brown, Peter T.
Shepherd, Douglas P.
Poulikakos, Lisa V.
author_facet Roy, Tamal
Brown, Peter T.
Shepherd, Douglas P.
Poulikakos, Lisa V.
contents Structured illumination microscopy (SIM) achieves superresolution in fluorescence imaging through patterned illumination and computational image reconstruction, yet current methods require bulky, costly modulation optics and high-precision optical alignment. This work demonstrates how nano-optical metasurfaces, rationally designed to tailor the optical wavefront at sub-wavelength dimensions, hold great potential as ultrathin, single-surface, all-optical wavefront modulators for SIM. We computationally demonstrate this principle with a multipolar-resonant metasurface composed of silicon nanostructures which generate versatile optical wavefronts in the far field upon variation of the polarization or angle of incident light. Algorithmic optimization is performed to identify the seven most suitable illumination patterns for SIM generated by the metasurface based on three key criteria. We find that multipolar-resonant metasurface SIM (mrm-SIM) achieves resolution comparable to conventional methods by applying the seven optimal metasurface-generated wavefronts to simulated fluorescent objects and reconstructing the objects using proximal gradient descent. The work presented here paves the way for a metasurface-enabled experimental simplification of structured illumination microscopy.
format Preprint
id arxiv_https___arxiv_org_abs_2309_14456
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Spatial wavefront shaping with a multipolar-resonant metasurface for structured illumination microscopy
Roy, Tamal
Brown, Peter T.
Shepherd, Douglas P.
Poulikakos, Lisa V.
Optics
Structured illumination microscopy (SIM) achieves superresolution in fluorescence imaging through patterned illumination and computational image reconstruction, yet current methods require bulky, costly modulation optics and high-precision optical alignment. This work demonstrates how nano-optical metasurfaces, rationally designed to tailor the optical wavefront at sub-wavelength dimensions, hold great potential as ultrathin, single-surface, all-optical wavefront modulators for SIM. We computationally demonstrate this principle with a multipolar-resonant metasurface composed of silicon nanostructures which generate versatile optical wavefronts in the far field upon variation of the polarization or angle of incident light. Algorithmic optimization is performed to identify the seven most suitable illumination patterns for SIM generated by the metasurface based on three key criteria. We find that multipolar-resonant metasurface SIM (mrm-SIM) achieves resolution comparable to conventional methods by applying the seven optimal metasurface-generated wavefronts to simulated fluorescent objects and reconstructing the objects using proximal gradient descent. The work presented here paves the way for a metasurface-enabled experimental simplification of structured illumination microscopy.
title Spatial wavefront shaping with a multipolar-resonant metasurface for structured illumination microscopy
topic Optics
url https://arxiv.org/abs/2309.14456