Knotting fractional-order knots with the polarization state of light

The fundamental polarization singularities of monochromatic light are normally associated with invariance under coordinated rotations: symmetry operations that rotate the spatial dependence of an electromagnetic field by an angle θ and its polarization by a multiple γθ of that angle. These symmetrie...

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Bibliographic Details
Published in:Nature photonics 2019-08, Vol.13 (8), p.569-574
Main Authors: Pisanty, Emilio, Machado, Gerard J., Vicuña-Hernández, Verónica, Picón, Antonio, Celi, Alessio, Torres, Juan P., Lewenstein, Maciej
Format: Article
Language:English
Subjects:
639/624/1107
639/624/1111
639/624/400
639/624/400/385
Angular momentum
Applied and Technical Physics
Beams (radiation)
Circular polarization
Dependence
Electromagnetic fields
Integers
Knots
Optical polarization
Physics
Physics and Astronomy
Polarization
Quantum Physics
Singularities
Subgroups
Symmetry
Tensors
Topology
Toruses
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Summary:The fundamental polarization singularities of monochromatic light are normally associated with invariance under coordinated rotations: symmetry operations that rotate the spatial dependence of an electromagnetic field by an angle θ and its polarization by a multiple γθ of that angle. These symmetries are generated by mixed angular momenta of the form J γ  =  L  +  γS , and they generally induce Möbius-strip topologies, with the coordination parameter γ restricted to integer and half-integer values. In this work we construct beams of light that are invariant under coordinated rotations for arbitrary rational γ , by exploiting the higher internal symmetry of ‘bicircular’ superpositions of counter-rotating circularly polarized beams at different frequencies. We show that these beams have the topology of a torus knot, which reflects the subgroup generated by the torus-knot angular momentum J γ , and we characterize the resulting optical polarization singularity using third- and higher-order field moment tensors, which we experimentally observe using nonlinear polarization tomography. The polarization structure around polarization singularities can exhibit arbitrary fractional rotations when tracing around the singularity, due to an underlying topology of a torus knot imprinted by the chosen ratio of frequencies contained in the light beam.
ISSN:1749-4885
1749-4893
DOI:10.1038/s41566-019-0450-2