Porfirev Alexey Petrovich

Publications in Math-Net.Ru

1. Phase singularities and optical vortices in photonics
   
   UFN, 192:8 (2022),  841–866
2. Spiral phase plate with multiple singularity centers
   
   Computer Optics, 44:6 (2020),  901–908
3. Experimental investigation of the energy backflow in the tight focal spot
   
   Computer Optics, 44:6 (2020),  863–870
4. Birth of optical vortices in propagating fields with an original fractional topological charge
   
   Computer Optics, 44:4 (2020),  493–500
5. Transfer of spin angular momentum to a dielectric particle
   
   Computer Optics, 44:3 (2020),  333–342
6. Diffractive optical elements for multiplexing structured laser beams
   
   Kvantovaya Elektronika, 50:7 (2020),  629–635
7. Topological stability of optical vortices diffracted by a random phase screen
   
   Computer Optics, 43:6 (2019),  917–925
8. Measurement of the orbital angular momentum of an astigmatic Hermite–Gaussian beam
   
   Computer Optics, 43:3 (2019),  356–367
9. Methods for determining the orbital angular momentum of a laser beam
   
   Computer Optics, 43:1 (2019),  42–53
10. Optical and structural phenomena at multipulse interference femtosecond laser fabrication of metasurfaces on a thin film of amorphous silicon
    
    Pis'ma v Zh. Èksper. Teoret. Fiz., 110:11 (2019),  759–764
11. Symmetric nanostructuring and plasmonic excitation of gold nanostructures by femtosecond Laguerre–Gaussian laser beams
    
    Kvantovaya Elektronika, 49:7 (2019),  666–671
12. A variety of Fourier-invariant Gaussian beams
    
    Computer Optics, 42:5 (2018),  727–735
13. Observation of an optical "angular tractor" effect in a Bessel beam
    
    Computer Optics, 42:4 (2018),  550–556
14. Orbital angular momentum of an astigmatic Hermite-Gaussian beam
    
    Computer Optics, 42:1 (2018),  13–21
15. Polarization-selective excitation of dye luminescence on a gold film by structured ultrashort laser pulses
    
    Pis'ma v Zh. Èksper. Teoret. Fiz., 107:1 (2018),  18–22
16. Generation of closely located light spots using specular Airy laser beams
    
    Computer Optics, 41:5 (2017),  661–669
17. Orbital angular momentum of an elliptic optical vortex embedded into the Gaussian beam
    
    Computer Optics, 41:3 (2017),  330–337
18. Fractional orbital angular momentum of a Gaussian beam with an embedded off-axis optical vortex
    
    Computer Optics, 41:1 (2017),  22–29
19. Determination of an optical vortex topological charge using an astigmatic transform
    
    Computer Optics, 40:6 (2016),  781–792
20. Generating a perfect optical vortex: comparison of approaches
    
    Computer Optics, 40:3 (2016),  312–321
21. Transfer of orbital angular momentum from asymmetric Laguerre-Gaussian beams to dielectric microparticles
    
    Computer Optics, 40:3 (2016),  305–311
22. Optical trapping and moving of microparticles using asymmetrical Bessel-Gaussian beams
    
    Computer Optics, 40:2 (2016),  152–157
23. An imaging spectrometer based on a discrete interference filter
    
    Computer Optics, 39:5 (2015),  716–720
24. Study of focusing into closely spaced spots via illuminating a diffractive optical element by a short-pulse laser beam
    
    Computer Optics, 39:2 (2015),  187–196
25. Research of orbital angular momentum of superpositions of diffraction-free Bessel beams with a complex shift
    
    Computer Optics, 39:2 (2015),  172–180
26. Sharp focusing of linearly polarized asymmetric Bessel beam
    
    Computer Optics, 39:1 (2015),  36–44
27. Manipulation of light-absorbing particles in air with optical bottle arrays
    
    Computer Optics, 38:4 (2014),  722–726
28. Manipulation of micro-objects using linear traps generated by vortex axicons
    
    Computer Optics, 38:4 (2014),  717–721
29. Generation of half-pearcey laser beams by a spatial light modulator
    
    Computer Optics, 38:4 (2014),  658–662
30. Hermite–Haussian laser beams with orbital angular momentum
    
    Computer Optics, 38:4 (2014),  651–657
31. A simple method of the formation nondiffracting hollow optical beams with intensity distribution in form of a regular polygon contour
    
    Computer Optics, 38:2 (2014),  243–248