Alexey Okulov
Alexey Okulov | |
---|---|
Born | Russian SFSR, Soviet Union | 12 July 1956
Nationality | Russian |
Alma mater | Moscow Institute of Physics and Technology |
Known for | Phase conjugation, Michelson interferometer, Bose–Einstein condensate, Angular momentum of light, Chaos theory, Soliton |
Awards |
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Scientific career | |
Fields | Laser Physics, Theoretical Physics |
Institutions | Lebedev Physical Institute,
A.M.Prokhorov General Physics Institute, Moscow Institute of Physics and Technology |
Thesis | Periodicity and Chaos in Structured Light |
Alexey Okulov (Russian: Алексей Юрьевич Окулов) is a Soviet and Russian physicist, the author of pioneering works in laser physics and theoretical physics.
Biography[]
Joined Lebedev Physical Institute Moscow in October 1979. Graduated from Moscow Institute of Physics and Technology in 1980, PhD from Lebedev Physical Institute, thesis "Periodicity and Chaos in Structured Light" in 1994.
Research[]
A.Yu. Okulov made substantial contributions in the optical phase conjugation, angular momentum of light, ultracold atoms theory and chaos theory. In 1979-1980 he made the seminal experiments on coherent summation of laser beams via Optical phase conjugation in stimulated Brillouin scattering.[1] The Michelson interferometer had been used to demonstrate the universal method for robust coherent summation of laser beams with complex amplitude and phase profile. The nontrivial feature of Michelson interferometer with stimulated Brillouin scattering mirror is that interference pattern is insensitive to wavelength-scale phase distortions. This gives the unique opportunity to use binary tree of beamsplitters for coherent addition of laser amplifiers.[2] Constructive interference in an array containing beamsplitters of laser beams synchronized by phase conjugation may increase the brightness of output amplified beam as .
This work demonstrated that linewidth of the stimulated Brillouin scattering phase conjugate mirror is due to stepwise phase fluctuations[3] rather than phase diffusion responsible for conventional Schawlow-Townes Laser linewidth.[4]
In 2014 Dr. Okulov had shown that such binary-tree Michelson phase-conjugator with degenerate four-wave mixing Kerr nonlinear mirror could be used for coherent summation[5] of chirped-pulse fiber laser amplifiers.[6]
In a field of Structured light Dr.Okulov proved theoretically that angular momentum of light is reversed in exactly opposite direction in optical phase conjugation mirror.[7] He had shown that due to conservation of angular momentum the optical phase conjugation mirror experiences the optical torque. For these symmetry reasons the acoustical vortices are excited inside stimulated Brillouin scattering phase-conjugating mirror.[8] He suggested robust Sagnac-like interferometer for the perfect optical phase conjugation of vortex photons.[9]
A.Yu.Okulov built exact theory for the quantum condensed matter trapped by optical vortices in Gross–Pitaevskii equation mean field approach.[10] He found exact solutions describing superfluid motion in twisted optical potential mounted in slowly rotating reference frame[11]
In a field of nonlinear dynamics of lasers Alexey Okulov introduced robust and computationally efficient method of infinite dimensional maps. The nonlinear spatiotemporal effects in laser pulse propagation as spatial solitons, Talbot effect[12] and vortex lattices are computed via fast Fourier transform (FFT) and iterates of nonlinear integral mappings known from Chaos theory.[13]
- Member of the Optical Society since 1995
- Member of the APS since 1995
- Member of the SPIE since 1997
- Member of the DPG since 2021
See also[]
- Gross–Pitaevskii equation
- Optical vortex
- Angular momentum
- Orbital angular momentum of light
- Chaos theory
- Chirped pulse amplification
- Soliton (optics)
- Self-focusing
- Michelson interferometer
- Nonlinear optics
- Talbot cavity
- Coherent addition
- Disk laser
References[]
- ^ Basov, N G; Zubarev, I G; Mironov, A B; Michailov, S I; Okulov, A Yu (1980). "Laser interferometer with wavefront reversing mirrors". Sov. Phys. JETP. 52 (5): 847. Bibcode:1980ZhETF..79.1678B.
- ^ Bowers, M W; Boyd, R W; Hankla, A K (1997). "Brillouin-enhanced four-wave-mixing vector phase-conjugate mirror with beam-combining capability". Optics Letters. 22 (6): 360–362. Bibcode:1997OptL...22..360B. doi:10.1364/OL.22.000360. PMID 18183201.
- ^ Basov, N G; Zubarev, I G; Mironov, A B; Michailov, S I; Okulov, A Yu (1980). "Phase fluctuations of the Stockes wave produced as a result of stimulated scattering of light". Sov. Phys. JETP Lett. 31 (11): 645. Bibcode:1980JETPL..31..645B.
- ^ Schawlow, A. L.; Townes, C. H. (1958). "Infrared and optical masers". Physical Review. 112 (6): 1940–1949. Bibcode:1958PhRv..112.1940S. doi:10.1103/PhysRev.112.1940.
- ^ Okulov, A Yu (2014). "Coherent chirped pulse laser network with Mickelson phase conjugator". Applied Optics. 53 (11): 2302–2311. arXiv:1311.6703. Bibcode:2014ApOpt..53.2302O. doi:10.1364/AO.53.002302. PMID 24787398.
- ^ Strickland, Donna; Mourou, Gerard (1985). "Compression of amplified chirped optical pulses". Optics Communications. Elsevier BV. 56 (3): 219–221. Bibcode:1985OptCo..56..219S. CiteSeerX 10.1.1.673.148. doi:10.1016/0030-4018(85)90120-8. ISSN 0030-4018.
- ^ Okulov, A Yu (2008). "Angular momentum of photons and phase conjugation". Journal of Physics B: Atomic, Molecular and Optical Physics. 41 (10): 101001. arXiv:0801.2675. Bibcode:2008JPhB...41j1001O. doi:10.1088/0953-4075/41/10/101001.
- ^ Okulov, A.Y. (2008). "Optical and Sound Helical structures in a stimulated Mandelstam – Brillouin mirror". JETP Letters (in Russian). 88 (8): 561–566. Bibcode:2008JETPL..88..487O. doi:10.1134/s0021364008200046. S2CID 120371573. Archived from the original on 2015-12-22. Retrieved 2015-10-31.
- ^ Okulov, A Yu (2010). "Phase-conjugation of the isolated optical vortex using a flat surfaces". JOSA B. 27 (11): 2424–2427. arXiv:1006.2778. Bibcode:2010JOSAB..27.2424O. doi:10.1364/JOSAB.27.002424. S2CID 55949729.
- ^ A. Yu. Okulov (2012). "Cold matter trapping via slowly rotating helical potential". Phys. Lett. A. 376 (4): 650–655. arXiv:1005.4213. Bibcode:2012PhLA..376..650O. doi:10.1016/j.physleta.2011.11.033. S2CID 119196009.
- ^ a b A. Yu. Okulov (2013). "Superfluid rotation sensor with helical laser trap". J. Low Temp. Phys. 171 (3): 397–407. arXiv:1207.3537. Bibcode:2013JLTP..171..397O. doi:10.1007/s10909-012-0837-7. S2CID 118601627.
- ^ Okulov, A Yu (1990). "Two-dimensional periodic structures in nonlinear resonator". JOSA B. 7 (6): 1045–1050. Bibcode:1990JOSAB...7.1045O. doi:10.1364/JOSAB.7.001045.
- ^ Okulov, A Yu (2020). "Structured light entities, chaos and nonlocal maps". Chaos, Solitons & Fractals. 133 (4): 109638. arXiv:1901.09274. Bibcode:2020CSF...13309638O. doi:10.1016/j.chaos.2020.109638.
- 1956 births
- Living people
- Moscow Institute of Physics and Technology alumni
- Moscow Institute of Physics and Technology faculty
- Quantum optics
- Russian academics
- Quantum mechanics