GENERATION THE LONGITUDINAL COMPONENT OF ELECTRIC FIELD ON THE OPTICAL AXIS USING ASYMMETRIC BINARY AXICONS ILLUMINATED BY LINEARLY AND CIRCULARLY POLARIZED BEAMS
(Стр. 43-46)
Подробнее об авторах
Khonina Svetlana N.
Doctor of Science in Physics and Mathematics, professor
Image Processing Systems Institute of the Russian Academy of Sciences, Samara State Aerospace University, Samara
Image Processing Systems Institute of the Russian Academy of Sciences, Samara State Aerospace University, Samara
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Аннотация:
It is analytically and numerically shown that by introducing the asymmetry into the axicon design it becomes possible to generate the longitudinal electric field (E-field) component on the optical axis for linearly and circularly polarized incident beams. Binary axicons with high numerical aperture (NA) in three configurations (axis-symmetric, spiral and bi-axicon) are investigated. Experimental measurements for the near-field diffraction of linearly and circularly polarized incident beams are presented.
Образец цитирования:
Khonina S.N., (2014), GENERATION THE LONGITUDINAL COMPONENT OF ELECTRIC FIELD ON THE OPTICAL AXIS USING ASYMMETRIC BINARY AXICONS ILLUMINATED BY LINEARLY AND CIRCULARLY POLARIZED BEAMS. Computational nanotechnology, 1 => 43-46.
Список литературы:
V.P. Kalosha and I. Golub, "Toward the subdiffraction focusing limit of optical superresolution," Opt. Lett. 32, 3540-3542 (2007).
T. Grosjean, D. Courjon, "Smallest focal spots," Opt. Comm. 272, 314-319 (2007).
V.V. Kotlyar, A.A. Kovalev, and S.S. Stafeev, "Sharp focus area of radially polarized Gaussian beam propagation through an axicon," Progress In Electromagnetic Research C, 5, 35-43 (2008).
R. Dorn, S. Quabis, and G. Leuchs, "Sharper focus for a radially polarized light beam," Phys. Rev. Lett. 91, 233901 (2003).
Y. Zhang, L. Wang, C. Zheng, "Vector propagation of radially polarized Gaussian beams diffracted by an axicon," J. Opt. Soc. Am. A. 22(11), 2542- 2546 (2005).
S.N. Khonina, N.L. Kazanskiy, A.V. Ustinov and S.G. Volotovskiy, "The lensacon: nonparaxial effects," J. Opt. Technol. 78(11), 724-729 (2011).
Q. Zhan, "Cylindrical vector beams: from mathematical concepts to applications," Advances in Optics and Photonics. 1, 1-57 (2009).
T. Grosjean and D. Courjon, "Photopolymers as vectorial sensors of the electric field," Opt. Expr. 14(6), 2203-2210 (2006). [9] Khonina S. N. and Golub I., "Optimization of focusing of linearly polarized light," Opt. Lett. 36(3), 352-354 (2011).
S.N. Khonina, D.V. Nesterenko, A.A. Morozov, R.V. Skidanov, V.A. Soifer, "Narrowing of a light spot at diffraction of linearly polarized beam on binary asymmetric axicons," Optical Memory and Neural Networks (Information Optics), Allerton Press, 21(1), 17-26 (2012).
M. Mansuripur, "Certain computational aspects of vector diffraction problems," J. Opt. Soc. Am. A. 6(5), 786-805 (1989).
J. Wang, Q. Wang, M. Zhang, "Development and prospect of near-field optical measurements and characterizations," Front. Optoelectron. 5(2), 171 -181 (2012).
B. Jia, X. Gan and M. Gu, "Direct observation of a pure focused evanes- cent field of a high numerical aperture objective lens by scanning near-field optical microscopy," Appl. Phys. Letters 86, 131110 (2005).
S.N. Khonina, S.V. Karpeev, S.V. Alferov, D.A. Savelyev, J. Laukkanen, J. Turunen, Experimental demonstration of the generation of the longitudinal E-field component on the optical axis with high-numerical-aperture binary axicons illuminated by linearly and circularly polarized beams, J. Opt. 15, 085704 (9pp) (2013)
Methods for Computer Design of Diffractive Optical Elements, ed. V.A. Soifer, New York: Wiley & Sons, Inc., 765 (2002).
T. Grosjean, D. Courjon, "Smallest focal spots," Opt. Comm. 272, 314-319 (2007).
V.V. Kotlyar, A.A. Kovalev, and S.S. Stafeev, "Sharp focus area of radially polarized Gaussian beam propagation through an axicon," Progress In Electromagnetic Research C, 5, 35-43 (2008).
R. Dorn, S. Quabis, and G. Leuchs, "Sharper focus for a radially polarized light beam," Phys. Rev. Lett. 91, 233901 (2003).
Y. Zhang, L. Wang, C. Zheng, "Vector propagation of radially polarized Gaussian beams diffracted by an axicon," J. Opt. Soc. Am. A. 22(11), 2542- 2546 (2005).
S.N. Khonina, N.L. Kazanskiy, A.V. Ustinov and S.G. Volotovskiy, "The lensacon: nonparaxial effects," J. Opt. Technol. 78(11), 724-729 (2011).
Q. Zhan, "Cylindrical vector beams: from mathematical concepts to applications," Advances in Optics and Photonics. 1, 1-57 (2009).
T. Grosjean and D. Courjon, "Photopolymers as vectorial sensors of the electric field," Opt. Expr. 14(6), 2203-2210 (2006). [9] Khonina S. N. and Golub I., "Optimization of focusing of linearly polarized light," Opt. Lett. 36(3), 352-354 (2011).
S.N. Khonina, D.V. Nesterenko, A.A. Morozov, R.V. Skidanov, V.A. Soifer, "Narrowing of a light spot at diffraction of linearly polarized beam on binary asymmetric axicons," Optical Memory and Neural Networks (Information Optics), Allerton Press, 21(1), 17-26 (2012).
M. Mansuripur, "Certain computational aspects of vector diffraction problems," J. Opt. Soc. Am. A. 6(5), 786-805 (1989).
J. Wang, Q. Wang, M. Zhang, "Development and prospect of near-field optical measurements and characterizations," Front. Optoelectron. 5(2), 171 -181 (2012).
B. Jia, X. Gan and M. Gu, "Direct observation of a pure focused evanes- cent field of a high numerical aperture objective lens by scanning near-field optical microscopy," Appl. Phys. Letters 86, 131110 (2005).
S.N. Khonina, S.V. Karpeev, S.V. Alferov, D.A. Savelyev, J. Laukkanen, J. Turunen, Experimental demonstration of the generation of the longitudinal E-field component on the optical axis with high-numerical-aperture binary axicons illuminated by linearly and circularly polarized beams, J. Opt. 15, 085704 (9pp) (2013)
Methods for Computer Design of Diffractive Optical Elements, ed. V.A. Soifer, New York: Wiley & Sons, Inc., 765 (2002).
