ФОРМИРОВАНИЕ ПРОДОЛЬНОЙ КОМПОНЕНТЫ ЭЛЕКТРИЧЕСКОГО ПОЛЯ НА ОПТИЧЕСКОЙ ОСИ ПРИ ФОКУСИРОВКЕ ПУЧКОВ С ЛИНЕЙНОЙ И КРУГОВОЙ ПОЛЯРИЗАЦИЕЙ АСИММЕТРИЧНЫМИ БИНАРНЫМИ АКСИКОНАМИ
( Pp. 47-51)
More about authors
Honina Svetlana Nikolaevna
doktor fiz.-mat. nauk, professor
Federalnoe gosudarstvennoe byudzhetnoe uchrezhdenie nauki Institut sistem obrabotki izobrazheniy Rossiyskoy Aakademii Nauk, Samarskiy gosudarstvennyy aerokosmicheskiy universitet imeni akademika S.P. Koroleva (nacionalnyy issledovatelskiy universitet)
Federalnoe gosudarstvennoe byudzhetnoe uchrezhdenie nauki Institut sistem obrabotki izobrazheniy Rossiyskoy Aakademii Nauk, Samarskiy gosudarstvennyy aerokosmicheskiy universitet imeni akademika S.P. Koroleva (nacionalnyy issledovatelskiy universitet)
Abstract:
Рассмотрена дифракция лазерного излучения с однородной (линейной или круговой) поляризацией на высокоапертурных бинарных аксиконах с различной структурой. Проведён теоретический анализ дифракции на аксиконе с использованием разложения по плоским волнам, и показано, что в зависимости от поляризации на оптической оси концентрируется либо продольная, либо поперечная компоненты электрического поля. Аналитически и численно показано, что внесение асимметрии в структуру аксикона позволяет формировать на оптической оси продольную компоненту для однородно-поляризованного освещающего пучка. Рассмотрены бинарные аксиконы трёх конфигураций: осесимметричный, биаксикон и спиральный и приведены результаты экспериментальных измерений
How to Cite:
Honina S.N., (2014), ФОРМИРОВАНИЕ ПРОДОЛЬНОЙ КОМПОНЕНТЫ ЭЛЕКТРИЧЕСКОГО ПОЛЯ НА ОПТИЧЕСКОЙ ОСИ ПРИ ФОКУСИРОВКЕ ПУЧКОВ С ЛИНЕЙНОЙ И КРУГОВОЙ ПОЛЯРИЗАЦИЕЙ АСИММЕТРИЧНЫМИ БИНАРНЫМИ АКСИКОНАМИ. Computational Nanotechnology, 1 => 47-51.
Reference list:
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S.N. KHonina, D.V. Nesterenko, A.A. Morozov, R.V. Skidanov, I.A. Pustovoy, Eksperimental noe issledovanie difraktsii lineyno-polyarizovannogo Gaussova puchka na binarnykh mikroaksikonakh s periodom, blizkim k dline volny, Komp yuternaya optika. - 2011. - T. 35, № 1. - S. 11-21.
M. Mansuripur, Certain computational aspects of vector diffraction problems, J. Opt. Soc. Am. A. - 1989. - Vol. 6, N 5. - P. 786-805.
B. Jia, X. Gan and M. Gu, Direct observation of a pure focused evanescent field of a high numerical aperture objective lens by scanning near-field optical microscopy, Appl. Phys. Letters. - 2005. - Vol. 86. - P. 131110.
S.V. Karpeev, S.N. KHonina, S.V. Alfyerov, Issledovanie ostroy fokusirovki polyarizatsionno-neodnorodnykh lazernykh puchkov vysokogo poryadka metodami blizhnepol noy mikroskopii, Komp yuternaya optika. - 2012. - T. 36, № 4. - S. 506-510.
S.N. KHonina, S.V. Karpeev, S.V. Alfyerov, D.A. Savel ev, Eksperimental naya demonstratsiya formirovaniya prodol noy komponenty elektricheskogo polya na opticheskoy osi s pomoshch yu vysoko- aperturnykh binarnykh aksikonov pri lineynoy i krugovoy polyarizatsii osveshchayushchego puchka, Komp yuternaya optika. - 2013. - T. 37, № 1. - S. 76-87
Metody komp yuternoy optiki: Uchebnik // pod red. V.A. Soyfera. Izdanie 2-e, ispravlennoe. - M.: Fizmatlit, 2003. - 688 s.
S.N. KHonina, S.G. Volotovskiy, Issledovanie primeneniya aksikonov v vysokoaperturnoy fokusiruyushchey sisteme, Komp yuternaya optika. - 2010. - T. 34, № 1. - S. 35-51.
Y. Zhang, L. Wang, C. Zheng, Vector propagation of radially polarized Gaussian beams diffracted by an axicon, J. Opt. Soc. Am. A. - 2005. - Vol. 22, N 11. - P. 2542-2546.
T. Grosjean, F. Baida and D. Courjon, Conical optics: the solution to con ne light, Applied Optics. - 2007. - Vol. 46, N 11. - P. 1994-2000.
V.V. Kotlyar, S.S. Stafeev, Modelirovanie ostroy fokusirovki radial no-polyarizovannoy lazernoy mody s pomoshch yu konicheskogo i binarnogo mikroaksikonov, Komp yuternaya optika. - 2009. - T. 33, № 1. - S. 52-60.
S.N. Khonina, A.V. Ustinov, A.A. Kovalyov, S.G. Volotovsky, Near-field propagation of vortex beams: models and computation algorithms, Optical Memory and Neural Networks (Allerton Press). - 2014. - V. 23(2). - P. 50-73.
S.N. KHonina, N.L. Kazanskiy, A.V. Ustinov, S.G. Volotovskiy, Linzakon: neparaksial nye effekty, Opticheskiy zhurnal. - 2011. - T. 78, № 11. - C. 44-51.
Q. Zhan, Cylindrical vector beams: from mathematical concepts to applications, Advances in Optics and Photonics. - 2009. - V. 1. - P. 1457.
S.N. KHonina, A.V. Ustinov, S.G. Volotovskiy, A.A. Kovalyev, Raschyet difraktsii lineyno-polyarizovannogo ogranichennogo puchka s postoyannoy intensivnost yu na vysokoaperturnykh binarnykh mikroaksikonakh v blizhney zone, Komp yuternaya optika. - 2010. - T. 34, № 4. - S. 443-460.
S.N. KHonina, Formirovanie osevogo otrezka s umen shennym poperechnym razmerom dlya lineynoy polyarizatsii osveshchayushchego puchka s pomoshch yu vysokoaperturnykh binarnykh aksikonov, ne obladayushchikh osevoy simmetriey, Komp yuternaya optika. - 2010. - T. 34, № 4. - S. 461-468.
S.N. KHonina, D.V. Nesterenko, A.A. Morozov, R.V. Skidanov, I.A. Pustovoy, Eksperimental noe issledovanie difraktsii lineyno-polyarizovannogo Gaussova puchka na binarnykh mikroaksikonakh s periodom, blizkim k dline volny, Komp yuternaya optika. - 2011. - T. 35, № 1. - S. 11-21.
M. Mansuripur, Certain computational aspects of vector diffraction problems, J. Opt. Soc. Am. A. - 1989. - Vol. 6, N 5. - P. 786-805.
B. Jia, X. Gan and M. Gu, Direct observation of a pure focused evanescent field of a high numerical aperture objective lens by scanning near-field optical microscopy, Appl. Phys. Letters. - 2005. - Vol. 86. - P. 131110.
S.V. Karpeev, S.N. KHonina, S.V. Alfyerov, Issledovanie ostroy fokusirovki polyarizatsionno-neodnorodnykh lazernykh puchkov vysokogo poryadka metodami blizhnepol noy mikroskopii, Komp yuternaya optika. - 2012. - T. 36, № 4. - S. 506-510.
S.N. KHonina, S.V. Karpeev, S.V. Alfyerov, D.A. Savel ev, Eksperimental naya demonstratsiya formirovaniya prodol noy komponenty elektricheskogo polya na opticheskoy osi s pomoshch yu vysoko- aperturnykh binarnykh aksikonov pri lineynoy i krugovoy polyarizatsii osveshchayushchego puchka, Komp yuternaya optika. - 2013. - T. 37, № 1. - S. 76-87
Metody komp yuternoy optiki: Uchebnik // pod red. V.A. Soyfera. Izdanie 2-e, ispravlennoe. - M.: Fizmatlit, 2003. - 688 s.
Keywords:
asymmetric binary axicon, near field diffraction, the longitudinal component of the electric field.
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