Tuning the fields focused by a high NA lens using spirally polarized beams (Invited Paper)

Wackenhut, Frank; Zobiak, B.; Meixner, Alfred J.; Failla, and A. V.

doi:10.3788/col201715.030013

Cited by 3 publications

(1 citation statement)

References 16 publications

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“…The far-field focusing investigation by a high numerical objective (OB) has long been an attractive topic [1][2][3][4][5][6][7][8][9][10] . The tightly focused subwavelength spot, an either transversely [1] or axially super resolved spot [7] , or a specially shaped focal spot, such as a doughnut-like spot [4,11] , a long-needle-like spot [9,12] , or a complete spiral spot [10] , can always find potential applications in various fields, such as high-resolution optical microscopic fluorescence imaging [12,13] , optical trapping and manipulation [14][15][16] , optical data storage [17] , optical lithography [18] , plasmonic wave excitation [19] , and metamaterial fabrication [20] . Most of the applications are polarization-sensitive.…”

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Manipulation of the overall polarization orientation in the focal volume of high numerical objectives

Chen

Zhu

2018

中国光学快报

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We propose an approach for tuning the three-dimensional polarization of a focusing subwavelength spot by a high numerical aperture objective. The incident beams are composed of a radially polarized beam, an azimuthally polarized beam, and a linearly polarized beam with three different weighting factors, respectively. A specially designed adjustable amplitude angular selector is also inserted at the back aperture of the objective for tuning the polarization azimuthally. It is shown that any desired overall polarization orientation can be obtained. We calculated the overall polarization orientation in the focal volume. It is found that the polar angle of the overall polarization orientation can be arbitrarily tuned by the combination of a radially polarized beam and a linearly polarized beam with different weighting factors, and the azimuthal angle can be tuned by rotating the orientation of the linearly polarized beam azimuthally.

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Manipulation of the overall polarization orientation in the focal volume of high numerical objectives

Chen

Zhu

2018

中国光学快报

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Optimizing of Poynting vector and light intensity after secant gradient lens

Nalimov

Kotlyar

2020

2020 International Conference on Information Technology and Nanotechnology (ITNT)

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Energy flux of a vortex field focused using a secant gradient lens

Nalimov

2020

Computer Optics

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In this paper we simulated the focusing of left circular polarized beam with a second order phase vortex and a second-order cylindrical vector beam by a gradient index Mikaelian lens. It was shown numerically, that there is an area with a negative Poynting vector projection on Z axis, that can be called an area with backward energy flow. Using a cylindrical hole in the output surface of the lens and optimizing it one can obtain a negative flow, which will be situated in the maximum intensity region, unlike to previous papers, in which such backward energy flow regions were situated in a shadow area. Thereby, this lens will work as an “optical magnet”, it will attract Rayleigh particles (with diameter about 1/20 of the wavelength) to its surface.

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Tuning the fields focused by a high NA lens using spirally polarized beams (Invited Paper)

Cited by 3 publications

References 16 publications

Manipulation of the overall polarization orientation in the focal volume of high numerical objectives

Manipulation of the overall polarization orientation in the focal volume of high numerical objectives

Optimizing of Poynting vector and light intensity after secant gradient lens

Energy flux of a vortex field focused using a secant gradient lens

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