федеральное государственное автономное образовательное учреждение высшего образования
«Самарский национальный исследовательский университет имени академика С.П. Королева»

Дегтярев Сергей Александрович

  • НИЛ-35 (Научно-исследовательская лаборатория автоматизированных систем научных исследований), старший научный сотрудник
  • Кафедра технической кибернетики, доцент
  • Телефон: +7 (917) 157-88-43
  • Email: degtyarev.sa@ssau.ru
  • Адрес: Корпус 1, к. 404 ул. Молодогвардейская, 151

Scopus/WoS

2023
  • 1 Khorin P.A., Degtyarev S.A., Khonina S.N. Application Study of a Refractive Biconical Axicon for Azimuthal and Radial Polarization Detection // Photonics Russia 2023. — Vol. 17. Issue 5. № 5. — P. 394-406
  • 2 Sokolenko B., Shostka N., Karakchieva O. etc. Experimental demonstration of acoustically induced polarization-dependent fiber optical vortex inversion // Optics Letters 2023. — Vol. 48. Issue 16. № 16. — P. 4400-4403
  • 3 Algubili A.M., Degtyarev S.A., Karpeev S.V. etc. Refractive multi-conical elements for cylindrical vector beam generation // Proceedings of SPIE - The International Society for Optical Engineering. — 2023. — Vol. 12743.
  • 4 Khorin P.A., Algubili A.M., Degtyarev S.A. etc. Investigation of polarization transformations performed with a refractive bi-conical axicon using the FDTD method // Computer Optics 2023. — Vol. 47. Issue 5. № 5. — P. 742-750
  • 5 Pavelyev V.S., Khonina S.N., Degtyarev S.A. etc. Spiral and subwavelength binary axicons of terahertz range // AIP Conference Proceedings. — 2023. — Vol. 2752.
  • 6 Pavelyev V., Khonina S., Degtyarev S. etc. Subwavelength Diffractive Optical Elements for Generation of Terahertz Coherent Beams with Pre-Given Polarization State // Sensors (Basel, Switzerland) 2023. — Vol. 23. Issue 3. № 3.
2022
  • 1 Karpeev S.V., Podlipnov V.V., Degtyarev S.A. etc. Formation of high-order cylindrical vector beams with sector sandwich structures // Computer Optics 2022. — Vol. 46. Issue 5. № 5. — P. 682-691
  • 2 Degtyarev S.A., Karpeev S.V., Ivliev N.A. etc. Refractive Bi-Conic Axicon (Volcone) for Polarization Conversion of Monochromatic Radiation // PHOTONICS 2022. — Vol. 9. Issue 6. № 6.
  • 3 Savelyev D., Degtyarev S. Features of the Optical Vortices Diffraction on Silicon Ring Gratings // Optical Memory and Neural Networks (Information Optics) 2022. — Vol. 31. — P. 55-66
  • 4 Degtyarev S.A., Savelyev D.A. Generation and focusing of a second-order vector beam using a subwavelength optical element // Computer Optics 2022. — Vol. 46. Issue 1. — P. 39-47
2021
  • 1 Pavelyev V.S., Khonina S.N., Degtyarev S.A. etc. Subwavelength silicon terahertz optics for generation of coherent beams with pre-given polarization state // International Conference on Infrared, Millimeter, and Terahertz Waves, IRMMW-THz. — 2021. — Vol. 2021-August.
  • 2 Khonina S.N., Degtyarev S.A., Ustinov A.V. etc. Metalenses for the generation of vector Lissajous beams with a complex Poynting vector density // Optics Express 2021. — Vol. 29. Issue 12. — P. 18634-18645
  • 3 Alexeyev C.N., Degtyarev S.A., Lapin B.P. etc. Optical vortices and orbital angular momentum in strongly coupled optical fibers // Applied Optics 2021. — Vol. 60. Issue 11. — P. 2981-2989
  • 4 Gubaev M.S., Savelyev D.A., Strelkov Y.S. etc. Polarization Transformation with Refractive Axicon // Progress in Electromagnetics Research Symposium. — 2021. — Vol. 2021-November. — P. 867-876
  • 5 Pavelyev V.S., Degtyarev S.A., Tukmakov K.N. etc. Silicon subwavelength axicons for terahertz beam polarization transformation // Journal of Physics: Conference Series. — 2021. — Vol. 1745. Issue 1.
  • 6 Gubaev M. S. , Degtyarev S.A., Strelkov Y.S. etc. Vectorial beam generation with a conical refractive surface // Computer Optics 2021. — Vol. 45. Issue 6. — P. 828-838
2020
  • 1 Kazanskiy N.L., Butt M.A., Degtyarev S.A. etc. Achievements in the development of plasmonic waveguide sensors for measuring the refractive index // Computer Optics 2020. — Vol. 44. Issue 3. — P. 295-318
  • 2 Degtyarev S.A., Karpeev S.V., Fomchenkov S.A. Radially Polarized Beams Forming Using Phase-Compensated Sectorial Dichroic Plates // Journal of Physics: Conference Series. — 2020. — Vol. 1695. Issue 1.
  • 3 Degtyarev S.A., Porfirev A.P., Khonina S.N. Subwavelength gratings for creation and focusing of cylindrical vector beams // Journal of Physics: Conference Series. — 2020. — Vol. 1461. Issue 1.
  • 4 Degtyarev S.A., Savelyev D.A., Fomchenkov S.A. The calculation of subwavelength diffraction optical elements based on gratings with a variable period using high-performance computer systems // Proceedings of SPIE - The International Society for Optical Engineering. — 2020. — Vol. 11516.
  • 5 Pavelyev V.S., Khonina S.N., Tukmakov K.N. etc. Diffractive optics technologies for the control of high-power terahertz laser beams // Proceedings - International Conference Laser Optics 2020, ICLO 2020. — 2020. —
  • 6 Gubaev M. S. , Degtyarev S., Ustinov A. Calculation of the rays path in an axicon with a small opening angle // Proceedings of ITNT 2020 - 6th IEEE International Conference on Information Technology and Nanotechnology. — 2020. —
  • 7 Khonina S.N., Krasnov S. V. , Ustinov A.V. etc. Refractive twisted microaxicons // Optics Letters 2020. — Vol. 45. Issue 6. — P. 1334-1337
2019
  • 1 Degtyarev S.A., Savelyev D.A., Khonina S.N. Subwavelength Diffraction Grating with Continuous Ridges for Inverse Energy Flux Generation // Progress in Electromagnetics Research Symposium. — 2019. — Vol. 2019-June. — P. 2005-2010
  • 2 Degtyarev S., Savelyev D., Khonina S. etc. Metasurfaces with continuous ridges for inverse energy flux generation // Optics Express 2019. — Vol. 27. Issue 11. — P. 15129-15135
  • 3 Khonina S.N., Tukmakov K.N., Degtyarev S.A. etc. Design, fabrication and investigation of a subwavelength axicon for terahertz beam polarization transforming // Computer Optics 2019. — Vol. 43. Issue 5. — P. 756-764
  • 4 Khonina S.N., Savelyev D.A., Degtyarev S.A. etc. Metalens for creation of the longitudinally polarized photonic needle // Journal of Physics: Conference Series. — 2019. — Vol. 1368. Issue 2.
  • 5 Degtyarev S.A., Savelyev D.A., Karpeev S.V. Diffractive optical elements for the generating cylindrical beams of different orders // Computer Optics 2019. — Vol. 43. Issue 3. — P. 347-355
2018
  • 1 Porfirev A.P., Degtyarev S.A., Khonina S.N. Investigation of focusing features of a spiral binary axicon // Progress in Biomedical Optics and Imaging - Proceedings of SPIE. — 2018. — Vol. 10717.
  • 2 Butt M.A., Degtyarev S.A., Khonina S.N. Light confinement in a 90° double high mesa slot bend waveguide // Journal of Physics: Conference Series. — 2018. — Vol. 1096. Issue 1.
  • 3 Degtyarev S.A., Volotovskiy S. G. , Khonina S.N. Sublinearly chirped metalenses for forming abruptly autofocusing cylindrically polarized beams // Journal of the Optical Society of America B: Optical Physics 2018. — Vol. 35. Issue 8. — P. 1963-1969
  • 4 Degtyarev S.A., Khonina S.N. Subwavelength diffraction gratings with curved grooves to form cylindrical vector beams of different orders // Journal of Physics: Conference Series. — 2018. — Vol. 1096. Issue 1.
  • 5 Butt M.A., Degtyarev S.A., Khonina S.N. Au-SiO2-Si hybrid plasmonic waveguide micro-ring resonator sensor // Journal of Physics: Conference Series. — 2018. — Vol. 1124. Issue 5.
  • 6 Savelyev D.A., Degtyarev S.A. Investigation of vortex evanescent fields in the near zone of fiber taper and sub-wavelength diffractive axicon // Proceedings of SPIE - The International Society for Optical Engineering. — 2018. — Vol. 10774.
  • 7 Khonina S.N., Ustinov A.V., Degtyarev S.A. Inverse energy flux of focused radially polarized optical beams // Physical Review A 2018. — Vol. 98. Issue 4.
2017
  • 1 Butt M.A., Degtyarev S.A., Khonina S.N. etc. An evanescent field absorption gas sensor at mid-IR 3.39 μm wavelength // Journal of Modern Optics 2017. — Vol. 64. Issue 18. — P. 1892-1897
  • 2 Khorin P.A., Degtyarev S.A. Wavefront aberration analysis with a multi-order diffractive optical element // CEUR Workshop Proceedings. — 2017. — Vol. 1900. — P. 28-33
  • 3 Khonina S., Degtyarev S., Savelyev D. etc. Focused, evanescent, hollow, and collimated beams formed by microaxicons with different conical angles // Optics Express 2017. — Vol. 25. Issue 16. — P. 19052-19064
  • 4 Degtyarev S.A., Porfirev A.P., Khonina S.N. Zernike basis-matched multi-order diffractive optical elements for wavefront weak aberrations analysis // Proceedings of SPIE - The International Society for Optical Engineering. — 2017. — Vol. 10337.
2016
  • 1 Khonina S.N., Degtyarev S.A. Analysis of the formation of a longitudinally polarized optical needle by a lens and axicon under tightly focused conditions // Journal of Optical Technology 2016. — Vol. 83. Issue 4. — P. 197-205
  • 2 Podlipnov V.V., Porfirev A.P., Degtyarev S.A. etc. Diffractive axicons to increase the efficiency of solar cells // CEUR Workshop Proceedings. — 2016. — Vol. 1638. — P. 103-110
  • 3 Degtyarev S.A., Ustinov A.V., Khonina S.N. Micro-taper as focusing or scattering optical element // AIP Conference Proceedings. — 2016. — Vol. 1724.
  • 4 Degtyarev S.A. 3D simulation of focusing a laser beam by a dielectric conical microaxicon // Computer Optics 2016. — Vol. 40. Issue 4. — P. 588-593
  • 5 Degtyarev S.A., Orfirev A.P.P., Khonina S.N. Photonic nanohelix generated by a binary spiral axicon // Applied Optics 2016. — Vol. 55. Issue 12. — P. B44-B48
  • 6 Degtyarev S.A., Podlipnov V.V., Verma P. etc. 3D-simulation of silicon micro-ring resonator with Comsol // Proceedings of SPIE - The International Society for Optical Engineering. — 2016. — Vol. 10224.
  • 7 Degtyarev S.A., Porfirev A.P., Ustinov A.V. etc. Singular laser beams nanofocusing with dielectric nanostructures: Theoretical investigation // Journal of the Optical Society of America B: Optical Physics 2016. — Vol. 33. Issue 12. — P. 2480-2485
  • 8 Degtyarev S.A., Butt M.A., Khonina S.N. etc. Modelling of TiO2 based slot waveguides with high optical confinement in sharp bends // 2016 International Conference on Computing, Electronic and Electrical Engineering, ICE Cube 2016 - Proceedings. — 2016. — P. 10-13
  • 9 Degtyarev S.A., Porfirev A.P., Khonina S.N. etc. Demonstration of vortical beams spectral stability formed in non-zero diffraction orders // Journal of Physics: Conference Series. — 2016. — Vol. 735. Issue 1.
  • 10 Larkin A.S., Pushkarev D.V., Degtyarev S.A. etc. Generation of Hermite-Gaussian modes of high-power femtosecond laser radiation using binary-phase diffractive optical elements // Quantum Electronics 2016. — Vol. 46. Issue 8. — P. 733-737
  • 11 Degtyarev S.A., Porfirev A.P., Khonina S.N. etc. Design of diffractive micro-patterns with weak wavelength dependence // Progress in Biomedical Optics and Imaging - Proceedings of SPIE. — 2016. — Vol. 9917.
2015
  • 1 Degtyarev S.A., Ustinov A.V., Khonina S.N. Diffraction by an axicon with taking into consideration multiple internal reflections // CEUR Workshop Proceedings. — 2015. — Vol. 1490. — P. 27-36
  • 2 Kozlova E.S., Kotlyar V.V., Degtyarev S.A. Simulation of resonance focusing of a picosecond pulse by a dielectric microcylinder // Computer Optics 2015. — Vol. 39. Issue 1. — P. 45-51
  • 3 Paranin V. D. , Khonina S., Degtyarev S. etc. Transformation of Bessel beams passing through uniaxial y-cut crystal // International Conference on Transparent Optical Networks. — 2015. — Vol. 2015-August.
  • 4 Degtyarev S.A., Khonina S.N. Transmission of focused light signal through an apertured probe of a near-field scanning microscope // Pattern Recognition and Image Analysis 2015. — Vol. 25. Issue 2. — P. 306-313
  • 5 Degtyarev S.A., Serafimovich P.G. Focused Laser-Beam Scanning by the Apertured Probe of a Near-Field Microscope // Radiophysics and Quantum Electronics 2015. — Vol. 57. Issue 8-9. — P. 665-671
  • 6 Degtyarev S.A., Khonina S.N. Forming near-field helical intensity using a binary vortical axicon // Proceedings of SPIE - The International Society for Optical Engineering. — 2015. — Vol. 9450.
  • 7 Khonina S.N., Degtyarev S.A. A Longitudinally Polarized Beam Generated by a Binary Axicon // Journal of Russian Laser Research 2015. — Vol. 36. Issue 2. — P. 151-161
  • 8 Kozlova E.S., Kotlyar V.V., Degtyarev S.A. Modeling the resonance focusing of a picosecond laser pulse using a dielectric microcylinder // Journal of the Optical Society of America B: Optical Physics 2015. — Vol. 32. Issue 11. — P. 2352-2357
  • 9 Ustinov A.V., Degtyarev S.A., Khonina S.N. Diffraction by a conical axicon considering multiple internal reflections // Computer Optics 2015. — Vol. 39. Issue 4. — P. 500-507
  • 10 Khonina S.N., Degtyarev S.A., Porfirev A.P. etc. Study of Focusing into Closely Spaced Spots Via Illuminating a Diffractive Optical Element by a Short-Pulse Laser Beam // Computer Optics 2015. — Vol. 39. Issue 2. — P. 187-196
  • 11 Degtyarev S.A., Karsakov A.V., Branchevskaya E.S. etc. Influence of eye refractive surface curvature modification on the retinal image quality in the liou-brennan eye model // Computer Optics 2015. — Vol. 39. Issue 5. — P. 702-708
  • 12 Kozlova, E. S., Kotlyar, V. V., Degtyarev, S. A. SIMULATION OF RESONANCE FOCUSING OF A PI.OSECOND PULSE BY A DIELECTRIC MICROCYLINDER // Computer Optics 2015. — Vol. 39. Issue 1. — P. 45-51
2014
  • 1 Degtyarev S.A., Khonina S.N., Ustinov A.V. etc. Lightning-rod effect near sharp dielectric structures // Proceedings of SPIE - The International Society for Optical Engineering. — 2014. — Vol. 9533.
  • 2 Degtyarev S.A., Khonina S.N., Podlipnov V.V. Formation of spiral intensity by binary vortical axicon // Computer Optics 2014. — Vol. 38. Issue 2. — P. 237-242
  • 3 Khonina S.N., Ustinov A.V., Degtyarev S.A. Calculation of diffraction of laser radiation by a two-dimensional (Cylindrical) axicon with the high numerical aperture in various models // Computer Optics 2014. — Vol. 38. Issue 4. — P. 670-680
  • 4 Degtyarev S.A., Khonina S.N., Alferov S.V. etc. Theoretical and experimental study of aperture size effects on the polarization sensitivity of near-field microscopy fiber-optic probes // Proceedings of SPIE - The International Society for Optical Engineering. — 2014. — Vol. 9156.
  • 5 Degtyarev S.A., Ustinov A.V., Khonina S.N. Nanofocusing by sharp edges // Computer Optics 2014. — Vol. 38. Issue 4. — P. 629-637
2013
  • 1 Degtyarev S.A., Khonina S.N. Study of subwavelength localization of a radiation by forming closely spaced singular lines using of subwavelength features of the dielectric micro-relief // Computer Optics 2013. — Vol. 37. Issue 4. — P. 426-430

ВАК

2022
2020
2015
2014
2012
  • 1 ДЕГТЯРЕВ С.А., ХОНИНА С. Н. Острая фокусировка линейно-поляризованного вихревого пучка с помощью микроаксикона // Вестник Самарского государственного аэрокосмического университета. — 2012. — № 32(1). — С. 195-206
  • 2 ДЕГТЯРЕВ С.А. Влияние величины угла раскрыва на фокусирующую способность микроаксикона // Известия Самарского научного центра РАН. — 2012. — № 14(4). — С. 179-183

Другие

2023
  • 1 Силифонкин С.А., Дегтярев С.А. Прохождение лучей через поверхности второго порядка с учетом поляризации // IX Международная конференция и молодёжная школа «Информационные технологии и нанотехнологии» (ИТНТ-2023). — 2023. — Т. 1.
2022
  • 1 Савельев Д.А., Дегтярев С.А. Особенности дифракции оптических вихрей на кремниевых кольцевых решетках // VIII Международная конференция и молодежная школа Информационные технологии и нанотехнологии (ИТНТ-2022). — 2022. — Т. 1.
2020
  • 1 Губаев М.С., Дегтярев С.А., Устинов Андрей Владимирович Расчет хода лучей в аксиконе с малым углом раскрытия // XII Международная конференция «Фундаментальные проблемы оптики – 2020». — 2020. — С. 150-152
  • 2 Gubaev M.S., Degtyarev S.A., Ustinov Andrey Vladimirovich Расчет хода лучей в аксиконе с малым углом раскрытия // VI Международная конференция и молодёжная школа «Информационные технологии и нанотехнологии» (ИТНТ-2020). — 2020. — Vol. 1. — P. 615-619
2019
  • 1 Хонина С.Н., Дегтярев С.А., Савельев Д.А. Металинза для формирования продольно поляризованной фотонной иглы // V Международная конференция и молодежная школа «Информационные технологии и нанотехнологии» (ИТНТ-2019). — 2019. — Т. 1. — С. 546-549
2017
  • 1 Савельев Д.А., Дегтярев С.А., Хонина С.Н. Исследование вихревых затухающих полей в ближней зоне оптоволоконного тейпера и субволнового дифракционного аксикона // II НАУЧНЫЙ ФОРУМ ТЕЛЕКОММУНИКАЦИИ: ТЕОРИЯ И ТЕХНОЛОГИИ ТТТ-2017. Оптические технологии в телекоммуникациях ОТТ-2017. — 2017. — С. 79-80
  • 2 Verma P.., S.A. Degtyarev, Reddi A.N.K. etc. Computer-Aided Design and Simulation of TiO2 Micro-Ring Resonator, Materials of International Conference on Signal, Image Processing Communication and Automation // International Conference on Signal, Image Processing Communication and Automation 2017. — 2017. — P. 361-366
  • 3 Корнилин Д.В., Кудрявцев И.А., Дегтярев С.А. Моделирование дифракции микрочастиц загрязнения гидравлических жидкостей // Информационные технологии и нанотехнологии (ИТНТ-2017). — 2017. — С. 306-309
2016
  • 1 Подлипнов В.В., Порфирьев А.П., Дегтярев С.А. и др. ПРИМЕНЕНИЕ ДИФРАКЦИОННЫХ АКСИКОНОВ ДЛЯ УВЕЛИЧЕНИЯ ЭФФЕКТИВНОСТИ СОЛНЕЧНЫХ ЭЛЕМЕНТОВ // ИНФОРМАЦИОННЫЕ ТЕХНОЛОГИИ И НАНОТЕХНОЛОГИИ (КОНФЕРЕНЦИЯ ИТНТ-2016). — 2016. — С. 44-49
  • 2 Verma P.., Degtyarev S.A., Khonina S.N. etc. Simulation of titanium oxide micro-ring resonator using COMSOL Multiphysics // ICANN-2016. — 2016. — P. 396
2014
  • 1 ДЕГТЯРЕВ С.А., ХОНИНА С. Н. Формирование протяженного продольно-поляризованного лазерного пучка // VIII международная конференция «Фундаментальные проблемы оптики». — 2014. — С. 232-235
2012
  • 1 ДЕГТЯРЕВ С.А. Детектирование остросфокусированного лазерного излучения с преобладающей продольной компонентой электрического поля // Молодёжная научная школа по нанофотонике, Nanostructures: Physics and Technology. — 2012. — С. 50-52
  • 2 ДЕГТЯРЕВ С.А. Использование рефракционного аксикона для острой фокусировки вихревого линейно-поляризованного пучка // Конгресс молодых ученых. — 2012. — С. 139-141
2011
  • 1 KhONINA S. N., DEGTYaREV S.A. Subwavelength focusing of electromagnetic waves with phase’s singularity in the optical taper // Proceedings of Asia-Pacific Conferences on “Fundamental Problems of Opto- and Microelectronics (APCOM)”. — 2011. —
Публикации в новостях