Nalimov, Anton Gennadyevich

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Total publications: 37
Scientific articles: 37

Number of views:
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Abstract pages:3816
Full texts:1223
Associate professor
Candidate of physico-mathematical sciences


Graduated from Samara State Aerospace University (SSAU) in 2003. He received his Candidate of Phys & Math degree from SSAU in 2006. Currently, he works as an associate professor at SSAU's Technical Cybernetics sub-department and a researcher at the Image Processing Systems Institute of the Russian Academy of Sciences.
List of publications on Google Scholar
List of publications on ZentralBlatt

Publications in Math-Net.Ru
1. V. V. Kotlyar, A. A. Kovalev, A. G. Nalimov, “Transformation of a high-order edge dislocation to optical vortices (spiral dislocations)”, Computer Optics, 45:3 (2021),  319–323  mathnet
2. V. V. Kotlyar, A. A. Kovalev, A. G. Nalimov, “Astigmatic transformation of a set of edge dislocations embedded in a Gaussian beam”, Computer Optics, 45:2 (2021),  190–199  mathnet
3. A. G. Nalimov, S. S. Stafeev, “Linear to circular polarization conversion in the sharp focus of an optical vortex”, Computer Optics, 45:1 (2021),  13–18  mathnet
4. V. V. Kotlyar, A. G. Nalimov, “Evolution of an optical vortex with initial fractional topological charge”, Computer Optics, 45:1 (2021),  5–12  mathnet
5. A. G. Nalimov, “Optical force acting on a particle in the presence of a backward energy flow near the focus of a gradient lens”, Computer Optics, 44:6 (2020),  871–875  mathnet
6. V. V. Kotlyar, S. S. Stafeev, A. G. Nalimov, A. A. Kovalev, A. P. Porfirev, “Experimental investigation of the energy backflow in the tight focal spot”, Computer Optics, 44:6 (2020),  863–870  mathnet
7. A. G. Nalimov, “Energy flux of a vortex field focused using a secant gradient lens”, Computer Optics, 44:5 (2020),  707–711  mathnet
8. A. G. Nalimov, E. S. Kozlova, “Inversion of the longitudinal component of spin angular momentum in the focus of a left-handed circularly polarized beam”, Computer Optics, 44:5 (2020),  699–706  mathnet
9. A. G. Nalimov, S. S. Stafeev, “Rotation of an elliptical dielectric particle in the focus of a circularly polarized Gaussian beam”, Computer Optics, 44:4 (2020),  561–567  mathnet
10. V. V. Kotlyar, A. G. Nalimov, A. A. Kovalev, A. P. Porfirev, S. S. Stafeev, “Transfer of spin angular momentum to a dielectric particle”, Computer Optics, 44:3 (2020),  333–342  mathnet
11. S. S. Stafeev, E. S. Kozlova, A. G. Nalimov, “Focusing a second-order cylindrical vector beam with a gradient index Mikaelian lens”, Computer Optics, 44:1 (2020),  29–33  mathnet
12. V. V. Kotlyar, S. S. Stafeev, A. G. Nalimov, “Vortex energy flow in the tight focus of a non-vortex field with circular polarization”, Computer Optics, 44:1 (2020),  5–11  mathnet
13. V. V. Kotlyar, S. S. Stafeev, A. G. Nalimov, A. A. Kovalev, “Formation of the reverse flow of energy in a sharp focus”, Computer Optics, 43:5 (2019),  714–722  mathnet
14. A. G. Nalimov, V. V. Kotlyar, “Sharp focus of a circularly polarized optical vortex at the output of a metalens illuminated by linearly polarized light”, Computer Optics, 43:4 (2019),  528–534  mathnet
15. V. V. Kotlyar, A. G. Nalimov, S. S. Stafeev, “Comparison of backward flow values in the sharp focus of light fields with polarization and phase singularity”, Computer Optics, 43:2 (2019),  174–183  mathnet
16. S. S. Stafeev, A. G. Nalimov, L. O'Faolain, M. V. Kotlyar, “Effects of fabrication errors on the focusing performance of a sector metalens”, Computer Optics, 42:6 (2018),  970–976  mathnet
17. A. G. Nalimov, V. V. Kotlyar, T. V. Kononenko, V. I. Konov, “An X-ray diamond focuser based on an array of three-component elements”, Computer Optics, 42:6 (2018),  933–940  mathnet
18. S. S. Stafeev, A. G. Nalimov, V. V. Kotlyar, “Energy backflow in a focal spot of the cylindrical vector beam”, Computer Optics, 42:5 (2018),  744–750  mathnet
19. V. V. Kotlyar, A. G. Nalimov, “A spirally rotating backward flow of light”, Computer Optics, 42:4 (2018),  527–533  mathnet
20. V. V. Kotlyar, A. A. Kovalev, A. G. Nalimov, “Backward flow of energy for an optical vortex with arbitrary integer topological charge”, Computer Optics, 42:3 (2018),  408–413  mathnet
21. V. V. Kotlyar, A. G. Nalimov, S. S. Stafeev, “The near-axis backflow of energy in a tightly focused optical vortex with circular polarization”, Computer Optics, 42:3 (2018),  392–400  mathnet
22. S. S. Stafeev, A. G. Nalimov, “Longitudinal component of the Poynting vector of a tightly focused optical vortex with circular polarization”, Computer Optics, 42:2 (2018),  190–196  mathnet
23. A. G. Nalimov, V. V. Kotlyar, V. I. Konov, “Simulation of hard x-ray focusing using an array of cylindrical micro-holes in a diamond film”, Computer Optics, 41:6 (2017),  796–802  mathnet
24. A. G. Nalimov, “Modeling a high numerical aperture micrometalens with a varying number of sectors”, Computer Optics, 41:5 (2017),  655–660  mathnet
25. V. V. Kotlyar, A. G. Nalimov, “A vector optical vortex generated and focused using a metalens”, Computer Optics, 41:5 (2017),  645–654  mathnet
26. A. G. Nalimov, S. S. Stafeev, E. S. Kozlova, V. V. Kotlyar, L. O'Faolain, M. V. Kotlyar, “Subwavelength focusing of laser light using a chromium zone plate”, Computer Optics, 41:3 (2017),  356–362  mathnet
27. S. S. Stafeev, A. G. Nalimov, L. O'Faolain, M. V. Kotlyar, “Binary diffraction gratings for controlling polarization and phase of laser light [review]”, Computer Optics, 41:3 (2017),  299–314  mathnet
28. V. V. Kotlyar, A. G. Nalimov, S. S. Stafeev, L. O'Faolain, M. V. Kotlyar, “Thin metalens with high numerical aperture”, Computer Optics, 41:1 (2017),  5–12  mathnet
29. V. V. Kotlyar, A. G. Nalimov, “Tightly focused laser light with azimuthal polarization and singular phase”, Computer Optics, 40:5 (2016),  642–648  mathnet
30. S. S. Stafeev, A. G. Nalimov, M. V. Kotlyar, L. O'Faolain, “Subwavelength focusing of laser light of a mixture of linearly and azimuthally polarized beams”, Computer Optics, 40:4 (2016),  458–466  mathnet
31. V. V. Kotlyar, A. G. Nalimov, M. V. Kotlyar, “Modeling a polarization microlens to focus linearly polarized light into a near-circular subwavelength focal spot”, Computer Optics, 40:4 (2016),  451–457  mathnet
32. A. G. Nalimov, V. V. Kotlyar, “Sharp focusing of light using a planar gradient microlens”, Computer Optics, 40:2 (2016),  135–140  mathnet
33. S. S. Stafeev, M. V. Kotlyar, L. O'Faolain, A. G. Nalimov, V. V. Kotlyar, “A four-zone transmission azimuthal micropolarizer with phase shift”, Computer Optics, 40:1 (2016),  12–18  mathnet
34. S. S. Stafeev, A. G. Nalimov, M. V. Kotlyar, L. O'Faolain, “A four-zone reflective azimuthal micropolarizer”, Computer Optics, 39:5 (2015),  709–715  mathnet
35. E. S. Kozlova, V. V. Kotlyar, A. G. Nalimov, “Comparative modeling of amplitude and phase zone plates”, Computer Optics, 39:5 (2015),  687–693  mathnet
36. A. G. Nalimov, V. V. Kotlyar, “Use of combined zone plates as imaging optics for hard x-rays”, Computer Optics, 39:1 (2015),  52–57  mathnet
37. S. S. Stafeev, L. O'Faolain, M. I. Shanina (Kotlyar), A. G. Nalimov, V. V. Kotlyar, “Sharp focusing of a mixture of radially and linearly polarized beams using a binary microlens”, Computer Optics, 38:4 (2014),  606–613  mathnet
38. A. G. Nalimov, L. O'Faolain, S. S. Stafeev, M. I. Shanina, V. V. Kotlyar, “Reflected four-zones subwavelenghth mictooptics element for polarization conversion from linear to radial”, Computer Optics, 38:2 (2014),  229–236  mathnet

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