Optical vortex

An optical vortex (also known as a screw dislocation or phase singularity) is a zero of an optical field, a point of zero intensity. Research into the properties of vortices has thrived since a comprehensive paper by John Nye and Michael Berry, in 1974,[1] described the basic properties of "dislocations in wave trains". The research that followed became the core of what is now known as "singular optics".

Explanation

In an optical vortex, light is twisted like a corkscrew around its axis of travel. Because of the twisting, the light waves at the axis itself cancel each other out. When projected onto a flat surface, an optical vortex looks like a ring of light, with a dark hole in the center. This corkscrew of light, with darkness at the center, is called an optical vortex.

The vortex is given a number, called the topological charge, according to how many twists the light does in one wavelength. The number is always an integer, and can be positive or negative, depending on the direction of the twist. The higher the number of the twist, the faster the light is spinning around the axis. This spinning carries orbital angular momentum with the wave train, and will induce torque on an electric dipole.

This orbital angular momentum of light can be observed in the orbiting motion of trapped particles. Interfering an optical vortex with a plane wave of light reveals the spiral phase as concentric spirals. The number of arms in the spiral equals the topological charge.

Optical vortices are studied by creating them in the lab in various ways. They can be generated directly in a laser,[2] or a laser beam can be twisted into vortex using any of several methods, such as computer-generated holograms, spiral-phase delay structures, or birefringent vortices in materials.

Properties

An optical singularity is a zero of an optical field. The phase in the field circulates around these points of zero intensity (giving rise to the name vortex). Vortices are points in 2D fields and lines in 3D fields (as they have codimension two). Integrating the phase of the field around a path enclosing a vortex yields an integer multiple of 2π. This integer is known as the topological charge, or strength, of the vortex.

A hypergeometric-Gaussian mode (HyGG) has an optical vortex in its center. The beam, which has the form

is a solution to the paraxial wave equation (see paraxial approximation, and the Fourier optics article for the actual equation) consisting of the Bessel function. Photons in a hypergeometric-Gaussian beam have an orbital angular momentum of . The integer m also gives the strength of the vortex at the beam's centre. Spin angular momentum of circularly polarized light can be converted into orbital angular momentum.[3]

Creation

Several methods exist to create Hypergeometric-Gaussian modes, including with a spiral phase plate, computer-generated holograms, mode conversion, a q-plate, or a spatial light modulator.

Vortices created by CGH

Applications

There are a broad variety of applications of optical vortices in diverse areas of communications and imaging.

See also

References

  1. Nye, J. F.; M. V. Berry (1974). "Dislocations in wave trains" (PDF). Proceedings of the Royal Society of London, Series A. 336 (1605): 165–190. Bibcode:1974RSPSA.336..165N. doi:10.1098/rspa.1974.0012. Retrieved 2006-11-28.
  2. White, AG; Smith, CP; Heckenberg, NR; Rubinsztein-Dunlop, H; McDuff, R; Weiss, CO; Tamm, C (1991). "Interferometric measurements of phase singularities in the output of a visible laser". Journal of Modern Optics. 38 (12): 2531–2541. Bibcode:1991JMOp...38.2531W. doi:10.1080/09500349114552651.
  3. Marrucci, L.; Manzo, C; Paparo, D (2006). "Optical spin-to-orbital angular momentum conversion in inhomogeneous anisotropic media". Physical Review Letters. 96 (16): 163905. arXiv:0712.0099Freely accessible. Bibcode:2006PhRvL..96p3905M. doi:10.1103/PhysRevLett.96.163905. PMID 16712234.
  4. Heckenberg, NR; McDuff, R; Smith, CP; White, AG (1992). "Generation of optical phase singularities by computer-generated holograms". Optics Letters. 17 (3): 221–223. Bibcode:1992OptL...17..221H. doi:10.1364/OL.17.000221. PMID 19784282.
  5. Twisted radio beams could untangle the airwaves
  6. Utilization of Photon Orbital Angular Momentum in the Low-Frequency Radio Domain
  7. Yan, Yan (16 September 2014). "High-capacity millimetre-wave communications with orbital angular momentum multiplexing". Nature Communications. 5: 4876. doi:10.1038/ncomms5876. PMC 4175588Freely accessible. PMID 25224763.
  8. "'Twisted light' carries 2.5 terabits of data per second". BBC News. 2012-06-25. Retrieved 2012-06-25.
  9. Bozinovic, Nenad (June 2013). "Terabit-Scale Orbital Angular Momentum Mode Division Multiplexing in Fibers". Science. 340: 1545–1548. doi:10.1126/science.1237861. PMID 23812709.
  10. Gregg, Patrick (January 2015). "Conservation of orbital angular momentum in air-core optical fibers". Optica. 2: 267–270. doi:10.1364/optica.2.000267.
  11. Yan, Lu (September 2015). "Q-plate enabled spectrally diverse orbital-angular-momentum conversion for stimulated emission depletion microscopy". Optica. 2: 900–903. doi:10.1364/optica.2.000900.

External links

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