Guiding Wave Through Diffraction in Photonic Crystal Fiber

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Wave guidance in photonic crystal fibers can be understood through diffraction rather than reflection, emphasizing the role of scattering in wave propagation. The discussion explores the potential of extruding a planar diffractive element within a fiber to achieve specific wave patterns at the output, such as Bessel or Laguerre-Gauss beams. The concept involves using techniques like holography or spatial light modulation to create desired field patterns. The idea is to extend these techniques into three dimensions, akin to optical fibers, to effectively guide waves. This approach aligns with recent research, including insights from Prof. Canning's work on Fresnel fibers.
androz
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Hi,
Can someone tell me how a wave is guided (in a fiber for instance) thinking
in term of diffraction (or scattering) and not in term of successive
reflections.
And my second question is : would it be possible to "extrude" a plan
diffractive element in a fiber to guide wave and have the right diffractive
motion at the end of the "diffractive fiber" ?
 
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Could you rephrase/expound on your second question? I'm not understanding it.
 
Well,
Imagine you want a particular field pattern, a particular laser beam shape.
It is possible to use holograms or SPM to "create" a multifocus tool, ie
a sort of lattice of light spots for instance, or a particular beam shape
such as Laguerre-Gauss laser beams.
My question was : would it be possible to put a third dimension to this SPM or hologram, just like an optical fibre, in order to guide a wave, and have the desired field at the end of the fiber, such as a Bessel beam, or a Laguerre-Gauss beam...
I was thinking of it just after I read an article of Prof. Canning in
OpticsExpress this month about the so-called "Fresnel-fiber".
 
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