Origin of the super-resolution of microsphere-assisted imaging

Maslov, Alexey V.; Astratov, Vasily N.

doi:10.1063/5.0188450

Applied Physics Letters

2024

DOI: 10.1063/5.0188450

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Origin of the super-resolution of microsphere-assisted imaging

Alexey V. Maslov,

Vasily N. Astratov

Abstract: Theoretical explanation of the super-resolution imaging by contact microspheres created a point of attraction for nanoimaging research during the last decade with many models proposed, yet its origin remains largely elusive. Using a classical double slit object, the key factors responsible for this effect are identified by an ab initio imaging model comprising object illumination, wave scattering, and image reconstruction from the diffracted far fields. The scattering is found by a full-wave solution of the Ma… Show more

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Cited by 6 publications

References 29 publications

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Modeling microcylinder-assisted conventional, interference and confocal microscopy

Pahl,

Hüser,

Eckhardt

et al. 2024

EPJ Web Conf.

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We present how to develop virtual microcylinder- or microsphere-assisted surface topography measurement instruments. As the most critical part, the interaction between light, microcylinder and measurement object is considered based on the finite element method (FEM). Results are obtained for microcylinder-assisted conventional, interference, and confocal microscopes without necessity to repeat the time-consuming FEM simulations for each sensor.

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Modeling microcylinder-assisted conventional, interference and confocal microscopy

Pahl,

Hüser,

Eckhardt

et al. 2024

EPJ Web Conf.

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Effect of boundary conditions in modeling of microsphere-assisted imaging

Maslov

2024

Appl. Opt.

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Exploring the performance of label-free imaging relies heavily on adequate physical models and accurate numerical simulations. A particularly challenging situation is imaging through contact microspheres, which have demonstrated resolution values exceeding the diffraction limit. Here an ab initio modeling of microsphere-assisted imaging is reported and its results are analyzed. The key part of modeling is solving the light scattering problem, which requires handling a rather large computational domain and broad angle illumination made up of multiple mutually incoherent plane waves. To account for plane wave incidence, two simulation approaches are developed that differ only by boundary conditions–quasiperiodic and absorbing. The algorithms to find images in both approaches are discussed and the simulation results are compared for free space and microsphere-assisted imaging. It is shown that while the super-resolution in microsphere-assisted imaging can be demonstrated using both approaches, the latter allows a large reduction in the computational resources. This significantly extends the capability of the simulations, enabling a rigorous exploration of novel imaging regimes.

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Dielectric microparticles for enhanced optical imaging: an FDTD analysis of contrast and resolution

Bekirov,

Wang,

Luk’yanchuk

et al. 2024

J. Opt. Soc. Am. A

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This paper presents a comprehensive numerical analysis of super-resolution imaging using dielectric microparticles, employing the finite-difference time-domain (FDTD) method to elucidate the mechanisms that enable resolution enhancements beyond the diffraction limit. Our study demonstrates that dielectric microparticles can achieve a resolution of the order of 50 nm in the visible spectrum, surpassing traditional optical microscopy limits. By simulating the propagation of radiation through a microparticle–object system and generating optical images via a backward propagation technique, we reveal critical insights into how microparticles enhance image contrast and resolution. The study also explores the influence of various parameters, such as source coherence and particle–substrate interactions, on the image formation process. Our results not only validate the super-resolution capability of microparticle-assisted imaging but also provide a robust framework for further advancements in optical imaging technologies, with potential applications in fields requiring ultra-high-resolution visualization.

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Origin of the super-resolution of microsphere-assisted imaging

Cited by 6 publications

References 29 publications

Modeling microcylinder-assisted conventional, interference and confocal microscopy

Modeling microcylinder-assisted conventional, interference and confocal microscopy

Effect of boundary conditions in modeling of microsphere-assisted imaging

Dielectric microparticles for enhanced optical imaging: an FDTD analysis of contrast and resolution

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