Diffraction optical elements for the implementation of three-dimensional nanoscopy using rotating light fields

D. V. Prokopova; Прокопова Д. В.; I. Y. Eremchev; Еремчев И. Ю.; N. N. Losevsky; Лосевский Н. Н.; D. А. Belousov; Белоусов Д. А.; S. K. Golubtsov; Голубцов С. К.; S. P. Kotova; Котова С. П.; А. V. Naumov; Наумов А. В.

doi:10.31857/S0367676524120026

Diffraction optical elements for the implementation of three-dimensional nanoscopy using rotating light fields

Authors: Prokopova D.V.¹, Eremchev I.Y.²^,1, Losevsky N.N.¹, Belousov D.А.³, Golubtsov S.K.³, Kotova S.P.¹, Naumov А.V.¹^,4
Affiliations:
1. Lebedev Physical Institute of the Russian Academy of Sciences
2. Institute of Spectroscopy of the Russian Academy of Sciences
3. Institute of Automation and Electrometry of the Siberian Branch of the Russian Academy of Sciences
4. Moscow State Pedagogical University
Issue: Vol 88, No 12 (2024)
Pages: 1851-1857
Section: Nanooptics, photonics and coherent spectroscopy
URL: https://journals.rcsi.science/0367-6765/article/view/286461
DOI: https://doi.org/10.31857/S0367676524120026
EDN: https://elibrary.ru/EXXPUS
ID: 286461

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Abstract
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About the authors
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Abstract

Diffraction optical elements, made by contact printing on a bichrome gelatin and direct laser recording using photoresist, have been studied in order to modify the point-scattering function for the implementation of 3D ultrahigh-resolution fluorescence microscopy. It has been shown that these elements produce two-lobed, rotating light fields that can be used for 3D nanoscopy. Results of 3D subdiffractive localization of fluorescent labels, with an assessment of the accuracy of coordinate restoration, have also been presented.

Keywords

three-dimensional nanoscopy, spiral light beams, diffraction optical elements

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About the authors

D. V. Prokopova

Lebedev Physical Institute of the Russian Academy of Sciences

Author for correspondence.
Email: prokopovadv@lebedev.ru

Branch in Samara

Russian Federation, Samara

I. Y. Eremchev

Institute of Spectroscopy of the Russian Academy of Sciences; Lebedev Physical Institute of the Russian Academy of Sciences

Email: prokopovadv@lebedev.ru

Branch in Troitsk

Russian Federation, Moscow; Moscow

N. N. Losevsky

Lebedev Physical Institute of the Russian Academy of Sciences

Email: prokopovadv@lebedev.ru

Branch in Samara

Russian Federation, Samara

D. А. Belousov

Institute of Automation and Electrometry of the Siberian Branch of the Russian Academy of Sciences

Email: prokopovadv@lebedev.ru
Russian Federation, Novosibirsk

S. K. Golubtsov

Institute of Automation and Electrometry of the Siberian Branch of the Russian Academy of Sciences

Email: prokopovadv@lebedev.ru
Russian Federation, Novosibirsk

S. P. Kotova

Lebedev Physical Institute of the Russian Academy of Sciences

Email: prokopovadv@lebedev.ru

Branch in Samara

Russian Federation, Samara

А. V. Naumov

Lebedev Physical Institute of the Russian Academy of Sciences; Moscow State Pedagogical University

Email: prokopovadv@lebedev.ru

Branch in Troitsk

Russian Federation, Moscow; Moscow

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2. Fig. 1. Phase function of the DOE optimized for operation in a three-dimensional nanoscope (a). Intensity distributions formed by the DOE manufactured by direct laser writing on photoresist at different distances near the focal plane of a lens with F = 250 mm (b). The frame side size is 2 mm.

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3. Fig. 2. Installation diagram of a three-dimensional nanoscope with a stationary reflective DOE.

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4. Fig. 3. Two-lobe images of point fluorescent labels in a 3-D nanoscope with a stationary DOE; for different positions of the emitters relative to the focal plane of the microscope δz: −2 (a1); −1 (a2); 0 (a3) and 1.5 μm (a4). Dependence of the rotation angle of the two-lobe image α on the distance δz (b). Dots are experimentally measured values; the red line is a linear approximation of the dependence.

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5. Fig. 4. Accuracy of axial coordinate reconstruction. Dependence of the accuracy of longitudinal coordinate reconstruction of point fluorescent labels on the number of registered photons N for the tilt angle α ~ 0° (a). The inset shows an example of the distribution of reconstructed longitudinal coordinates z; obtained in a series of measurements n = 200 and its approximation by the Gaussian function. Dependence of the longitudinal coordinate reconstruction error σz(α) on the image rotation angle for a fixed number of photons N (b).

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