Controlling and shaping topological charge by means of spiral petal-like zone plate

•We introduced a petal-like spiral photon sieve.•This element produces two axial vortex beams.•This element generates optical corridor carrying topological charge.•Topological charge of the vortices is easily tailored using the petal frequency.•Vortex is annihilated when charge is an integer multipl...

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Bibliographic Details
Published in:Optics and laser technology 2021-02, Vol.134, p.106574, Article 106574
Main Authors: Golbandi, Marjan, Sabatyan, Arash
Format: Article
Language:English
Subjects:
Beam shaping
Current carriers
Electron beams
Fresnel zone plate
Optical vortex
Phase change
Singularity
Spiral zone plate
Topology
Zone plates
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Summary:•We introduced a petal-like spiral photon sieve.•This element produces two axial vortex beams.•This element generates optical corridor carrying topological charge.•Topological charge of the vortices is easily tailored using the petal frequency.•Vortex is annihilated when charge is an integer multiple of petal frequency. In this work, we present a technique based on a helically modulated petal zone plate through which topological charge is handled. Basically, in this case, we are dealing with two kinds of phase change, the first one is a sinusoidally azimuthal phase change and the second one is helically changing of the phase. We have shown that the total topological charge of the generated beam depends on the difference between the number of the petal and the charge of the element. Such that, the focused vortex beam turns to a focal spot when these two parameters take the same value, i.e. the singularity is quietly taken away. It was also demonstrated that a bi-annular vortex is generated for a large amount of petal frequency. As a result, an optical corridor carrying a topological charge is also formed around the focus.
ISSN:0030-3992
1879-2545
DOI:10.1016/j.optlastec.2020.106574