Open AccessSharper Focal Spot for a Radially Polarized Beam Using Ring Aperture with Phase Jump
Author(s) -
Svetla. Khonina,
Андрей Владимирович Устинов
Publication year - 2013
Publication title -
journal of engineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.244
H-Index - 20
eISSN - 2314-4912
pISSN - 2314-4904
DOI - 10.1155/2013/512971
Subject(s) - optics , diffraction , numerical aperture , angular aperture , radius , aperture (computer memory) , physics , focal length , intensity (physics) , bessel function , phase (matter) , full width at half maximum , bright spot , materials science , lens (geology) , wavelength , computer security , quantum mechanics , computer science , acoustics
We study analytically and numerically in which way the width of ring aperture containing a phase jump affects the size and intensity of the focal spot generated with a radially polarized beam. It is shown that by means of destructive interference of beams coming from the different-phase rings it becomes possible to overcome the scalar diffraction limit corresponding to the first zero of the zero-order Bessel function. The minimal focal spot size (FWHM ) is found to be attained when the annular aperture width amounts to 20% of the full-aperture radius. In this case, the side-lobe intensity is not larger than 30% of the central peak. A wider annular aperture with the phase jump introduced is also shown to form a focal spot not exceeding the diffraction limit for a narrow annular aperture, simultaneously providing a nearly six times higher intensity. In this case, the side lobes amount to 35% of the central peak.
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