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Перегляд НДІ Фізики за Автор "Angelsky, Oleg V."
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Документ Editorial: Singular and Correlation Optics(2021) Angelsky, Oleg V.; Bekshaiev, Oleksandr Yа.; Hanson, Steen G.; Mokhun, Igor I.; Vasnetsov, Mikhail V.; Wang, Wei; Бекшаєв, Олександр Янович; Бекшаев, Александр ЯновичSingularities in wave fields form a relatively young concept of wave physics originating from the seminal article by Nye and Berry. Initially, this concept seemed rather abstract and curious, but the development of laser optics has demonstrated the ubiquity of optical singularities and their exceptional power in characterization, control, and applications of light fields. The era of singular optics started, and now, it is difficult to indicate another area of optics that is developing so rapidly and steadily.Документ Editorial: Singular and Correlation Optics(2021) Angelsky, Oleg V.; Bekshaiev, Oleksandr Yа.; Бекшаєв, Олександр Янович; Бекшаев, Александр Янович; Hanson, Steen G.; Mokhun, Igor I.; Vasnetsov, Mikhail V.; Wang, WeiSingularities in wave fields form a relatively young concept of wave physics originating from the seminal article by Nye and Berry [1]. Initially, this concept seemed rather abstract and curious, but the development of laser optics has demonstrated the ubiquity of optical singularities and their exceptional power in characterization, control, and applications of light fields. The era of singular optics started [2, 3], and now, it is difficult to indicate another area of optics that is developing so rapidly and steadily.Документ Structured Light Control and Diagnostics Using Optical Crystals(2021) Angelsky, Oleg V.; Bekshaiev, Oleksandr Yа.; Drahan, Hryhorii S.; Maksimyak, P. P.; Zenkova, C. Yu.; Zheng, Jun; Бекшаєв, Олександр Янович; Бекшаев, Александр Янович; Драган, Григорій Сильвестрович; Драган, Григорий СильвестровичWe describe experimental results exposing the possibilities of optical crystals, especially anisotropic and birefringent, for creation, control, and diagnostics of structured light fields with singular and extraordinary properties. The efficiency of birefringent media is demonstrated for purposeful generation of optical beams with phase singularities (optical vortices) and desirable patterns of internal energy flows, in both the mono- and polychromatic light. On the other hand, anisotropic micro-objects can be used as probing bodies forinvestigationofthepeculiarfeaturesof internalenergy flowsandcorresponding momentumandangularmomentumdistributionsinstructuredlight fields.Inparticular,the specific mechanical action of light fields, formed under the total-reflection conditions, has been detected that confirms the existence of “extraordinary” dynamical characteristics of evanescent light waves predicted theoretically: the “transverse” momentum and “vertical” spinandtheirdependenceontheincidentbeampolarization.Theresultscanbeusefulfor the optical trapping and micromanipulation techniques, including the biomedical and pharmaceutical applications.Документ Structured Light: Ideas and Concepts(2020) Angelsky, Oleg V.; Bekshaiev, Oleksandr Yа.; Hanson, Steen G.; Zenkova, Claudia Yu.; Mokhun, Igor I.; Jun, ZhengThe paper briefly presents some essential concepts and features of light fields with strong spatial inhomogeneity of amplitude, phase, polarization, and other parameters. It contains a characterization of optical vortices, speckle fields, polarization singularities. A special attention is paid to the field dynamical characteristics (energy, momentum, angular momentum, and their derivatives), which are considered not only as mechanical attributes of the field but also as its meaningful and application-oriented descriptive parameters. Peculiar features of the light dynamical characteristics in inhomogeneous and dispersive media are discussed. The dynamical properties of paraxial beams and evanescent waves (including surface plasmon–polaritons) are analyzed in more detail; in particular, a general treatment of the extraordinary spin and momentum, orthogonal to the main propagation direction, is outlined. Applications of structured light fields for optical manipulation, metrology, probing, and data processing are described.