Nalimov Anton Gennadyevich

Publications in Math-Net.Ru

1. Focusing of linearly polarized optical vortex and a Hall effect
   
   Computer Optics, 48:1 (2024),  26–34
2. Calculation of the intensity at the sharp focus of a cylindrical vector beam by three methods
   
   Computer Optics, 47:5 (2023),  734–741
3. A metalens-based optical polarization sensor
   
   Computer Optics, 47:2 (2023),  208–214
4. Multifocal metalens for detecting several topological charges at different wavelengths
   
   Computer Optics, 47:2 (2023),  201–207
5. Astigmatic transformation of a fractional-order edge dislocation
   
   Computer Optics, 46:4 (2022),  522–530
6. Superposition of two Laguerre-Gaussian beams shifted from the optical axis
   
   Computer Optics, 46:3 (2022),  366–374
7. Topological charge of optical vortices in the far field with an initial fractional charge: optical "dipoles"
   
   Computer Optics, 46:2 (2022),  189–195
8. Off-axis elliptic Gaussian beams with an intrinsic orbital angular momentum
   
   Computer Optics, 45:6 (2021),  809–817
9. Focusing of a vector beam with C-lines of polarization singularity
   
   Computer Optics, 45:6 (2021),  800–808
10. Optical phase singularities going to and coming from infinity with a higher-than-light speed
    
    Computer Optics, 45:5 (2021),  654–660
11. Sharp focusing of beams with V-point polarization singularities
    
    Computer Optics, 45:5 (2021),  643–653
12. Transformation of a high-order edge dislocation to optical vortices (spiral dislocations)
    
    Computer Optics, 45:3 (2021),  319–323
13. Astigmatic transformation of a set of edge dislocations embedded in a Gaussian beam
    
    Computer Optics, 45:2 (2021),  190–199
14. Linear to circular polarization conversion in the sharp focus of an optical vortex
    
    Computer Optics, 45:1 (2021),  13–18
15. Evolution of an optical vortex with initial fractional topological charge
    
    Computer Optics, 45:1 (2021),  5–12
16. 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
17. Experimental investigation of the energy backflow in the tight focal spot
    
    Computer Optics, 44:6 (2020),  863–870
18. Energy flux of a vortex field focused using a secant gradient lens
    
    Computer Optics, 44:5 (2020),  707–711
19. 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
20. Rotation of an elliptical dielectric particle in the focus of a circularly polarized Gaussian beam
    
    Computer Optics, 44:4 (2020),  561–567
21. Transfer of spin angular momentum to a dielectric particle
    
    Computer Optics, 44:3 (2020),  333–342
22. Focusing a second-order cylindrical vector beam with a gradient index Mikaelian lens
    
    Computer Optics, 44:1 (2020),  29–33
23. Vortex energy flow in the tight focus of a non-vortex field with circular polarization
    
    Computer Optics, 44:1 (2020),  5–11
24. Formation of the reverse flow of energy in a sharp focus
    
    Computer Optics, 43:5 (2019),  714–722
25. 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
26. Comparison of backward flow values in the sharp focus of light fields with polarization and phase singularity
    
    Computer Optics, 43:2 (2019),  174–183
27. Effects of fabrication errors on the focusing performance of a sector metalens
    
    Computer Optics, 42:6 (2018),  970–976
28. An X-ray diamond focuser based on an array of three-component elements
    
    Computer Optics, 42:6 (2018),  933–940
29. Energy backflow in a focal spot of the cylindrical vector beam
    
    Computer Optics, 42:5 (2018),  744–750
30. A spirally rotating backward flow of light
    
    Computer Optics, 42:4 (2018),  527–533
31. Backward flow of energy for an optical vortex with arbitrary integer topological charge
    
    Computer Optics, 42:3 (2018),  408–413
32. The near-axis backflow of energy in a tightly focused optical vortex with circular polarization
    
    Computer Optics, 42:3 (2018),  392–400
33. Longitudinal component of the Poynting vector of a tightly focused optical vortex with circular polarization
    
    Computer Optics, 42:2 (2018),  190–196
34. Simulation of hard x-ray focusing using an array of cylindrical micro-holes in a diamond film
    
    Computer Optics, 41:6 (2017),  796–802
35. Modeling a high numerical aperture micrometalens with a varying number of sectors
    
    Computer Optics, 41:5 (2017),  655–660
36. A vector optical vortex generated and focused using a metalens
    
    Computer Optics, 41:5 (2017),  645–654
37. Subwavelength focusing of laser light using a chromium zone plate
    
    Computer Optics, 41:3 (2017),  356–362
38. Binary diffraction gratings for controlling polarization and phase of laser light [review]
    
    Computer Optics, 41:3 (2017),  299–314
39. Thin metalens with high numerical aperture
    
    Computer Optics, 41:1 (2017),  5–12
40. Tightly focused laser light with azimuthal polarization and singular phase
    
    Computer Optics, 40:5 (2016),  642–648
41. Subwavelength focusing of laser light of a mixture of linearly and azimuthally polarized beams
    
    Computer Optics, 40:4 (2016),  458–466
42. Modeling a polarization microlens to focus linearly polarized light into a near-circular subwavelength focal spot
    
    Computer Optics, 40:4 (2016),  451–457
43. Sharp focusing of light using a planar gradient microlens
    
    Computer Optics, 40:2 (2016),  135–140
44. A four-zone transmission azimuthal micropolarizer with phase shift
    
    Computer Optics, 40:1 (2016),  12–18
45. A four-zone reflective azimuthal micropolarizer
    
    Computer Optics, 39:5 (2015),  709–715
46. Comparative modeling of amplitude and phase zone plates
    
    Computer Optics, 39:5 (2015),  687–693
47. Use of combined zone plates as imaging optics for hard x-rays
    
    Computer Optics, 39:1 (2015),  52–57
48. Sharp focusing of a mixture of radially and linearly polarized beams using a binary microlens
    
    Computer Optics, 38:4 (2014),  606–613
49. Reflected four-zones subwavelenghth mictooptics element for polarization conversion from linear to radial
    
    Computer Optics, 38:2 (2014),  229–236