Stafeev Sergey Sergeevich

Publications in Math-Net.Ru

1. Losses and orbital part of the Poynting vector of air-core modes in hollow-core fibers
   
   Computer Optics, 48:2 (2024),  192–196
2. Beams with the transverse-only intensity at the focus
   
   Computer Optics, 48:2 (2024),  186–191
3. Focusing a cylindrical vector beam and the Hall effect
   
   Computer Optics, 48:1 (2024),  47–52
4. Spin angular momentum at the sharp focus of a cylindrical vector vortex beam
   
   Computer Optics, 47:6 (2023),  875–883
5. High-order optical Hall effect at the tight focus of laser radiation
   
   Computer Optics, 47:5 (2023),  710–715
6. Minimal focal spot obtained by focusing circularly polarized light
   
   Computer Optics, 47:3 (2023),  361–366
7. A metalens-based optical polarization sensor
   
   Computer Optics, 47:2 (2023),  208–214
8. Reverse energy flow in vector modes of optical fibers
   
   Computer Optics, 47:1 (2023),  36–39
9. Sharp focusing of on-axis superposition of a high-order cylindrical vector beam and a beam with linear polarization
   
   Computer Optics, 47:1 (2023),  5–15
10. Circular polarization before and after the sharp focus for linearly polarized light
    
    Computer Optics, 46:3 (2022),  381–387
11. Focusing of a vector beam with C-lines of polarization singularity
    
    Computer Optics, 45:6 (2021),  800–808
12. A minimal subwavelength focal spot for the energy flux
    
    Computer Optics, 45:5 (2021),  685–691
13. Sharp focusing of beams with V-point polarization singularities
    
    Computer Optics, 45:5 (2021),  643–653
14. An orbital energy flow and a spin flow at the tight focus
    
    Computer Optics, 45:4 (2021),  520–524
15. A transverse energy flow at the tight focus of light with higher-order circular-azimuthal polarization
    
    Computer Optics, 45:3 (2021),  311–318
16. Focusing fractional-order cylindrical vector beams
    
    Computer Optics, 45:2 (2021),  172–178
17. Transverse intensity at the tight focus of a second-order cylindrical vector beam
    
    Computer Optics, 45:2 (2021),  165–171
18. Linear to circular polarization conversion in the sharp focus of an optical vortex
    
    Computer Optics, 45:1 (2021),  13–18
19. The photonic nanojets formation by two-dimensional microprisms
    
    Computer Optics, 44:6 (2020),  909–916
20. Experimental investigation of the energy backflow in the tight focal spot
    
    Computer Optics, 44:6 (2020),  863–870
21. High numerical aperture metalens to generate an energy backflow
    
    Computer Optics, 44:5 (2020),  691–698
22. Toroidal polarization vortices in tightly focused beams with singularity
    
    Computer Optics, 44:5 (2020),  685–690
23. Rotation of an elliptical dielectric particle in the focus of a circularly polarized Gaussian beam
    
    Computer Optics, 44:4 (2020),  561–567
24. Transfer of spin angular momentum to a dielectric particle
    
    Computer Optics, 44:3 (2020),  333–342
25. Focusing a second-order cylindrical vector beam with a gradient index Mikaelian lens
    
    Computer Optics, 44:1 (2020),  29–33
26. Vortex energy flow in the tight focus of a non-vortex field with circular polarization
    
    Computer Optics, 44:1 (2020),  5–11
27. Formation of the reverse flow of energy in a sharp focus
    
    Computer Optics, 43:5 (2019),  714–722
28. Sharp focusing of a light field with polarization and phase singularities of an arbitrary order
    
    Computer Optics, 43:3 (2019),  337–346
29. Formation of an elongated region of energy backflow using ring apertures
    
    Computer Optics, 43:2 (2019),  193–199
30. Comparison of backward flow values in the sharp focus of light fields with polarization and phase singularity
    
    Computer Optics, 43:2 (2019),  174–183
31. Effects of fabrication errors on the focusing performance of a sector metalens
    
    Computer Optics, 42:6 (2018),  970–976
32. Energy backflow in a focal spot of the cylindrical vector beam
    
    Computer Optics, 42:5 (2018),  744–750
33. The near-axis backflow of energy in a tightly focused optical vortex with circular polarization
    
    Computer Optics, 42:3 (2018),  392–400
34. Rotation of two-petal laser beams in the near field of a spiral microaxicon
    
    Computer Optics, 42:3 (2018),  385–391
35. Longitudinal component of the Poynting vector of a tightly focused optical vortex with circular polarization
    
    Computer Optics, 42:2 (2018),  190–196
36. Subwavelength focusing of laser light using a chromium zone plate
    
    Computer Optics, 41:3 (2017),  356–362
37. Binary diffraction gratings for controlling polarization and phase of laser light [review]
    
    Computer Optics, 41:3 (2017),  299–314
38. Tight focusing of a sector-wise azimuthally polarized optical vortex
    
    Computer Optics, 41:2 (2017),  147–154
39. Thin metalens with high numerical aperture
    
    Computer Optics, 41:1 (2017),  5–12
40. Subwavelength focusing of laser light of a mixture of linearly and azimuthally polarized beams
    
    Computer Optics, 40:4 (2016),  458–466
41. A four-zone transmission azimuthal micropolarizer with phase shift
    
    Computer Optics, 40:1 (2016),  12–18
42. A four-zone reflective azimuthal micropolarizer
    
    Computer Optics, 39:5 (2015),  709–715
43. Sharp focusing of linearly polarized asymmetric Bessel beam
    
    Computer Optics, 39:1 (2015),  36–44
44. Sharp focusing of a mixture of radially and linearly polarized beams using a binary microlens
    
    Computer Optics, 38:4 (2014),  606–613
45. Polarizing and focusing properties of reflective Fresnel zone plate
    
    Computer Optics, 38:3 (2014),  456–462
46. Reflected four-zones subwavelenghth mictooptics element for polarization conversion from linear to radial
    
    Computer Optics, 38:2 (2014),  229–236
47. Photonic nanojets formed by square microsteps
    
    Computer Optics, 38:1 (2014),  72–80
48. Special aspects of subwavelength focal spot measurement using near-field optical microscope
    
    Computer Optics, 37:3 (2013),  332–340


49. Indexing of Computer Optics in the Emerging Sources Citation Index database
    
    Computer Optics, 41:4 (2017),  592