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Conical diffraction of linearly polarised light controls the angular position of a microscopic object

Conical diffraction of linearly polarised light in a biaxial crystal produces a beam with a crescent-shaped intensity profile. Rotation of the plane of polarisation produces the unique effect of spatially moving the crescent-shaped beam around a ring. We use this effect to trap microspheres and whit...

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Bibliographic Details
Published in:Optics express 2010-12, Vol.18 (26), p.27319-27326
Main Authors: O'Dwyer, D P, Phelan, C F, Ballantine, K E, Rakovich, Y P, Lunney, J G, Donegan, J F
Format: Article
Language:English
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Summary:Conical diffraction of linearly polarised light in a biaxial crystal produces a beam with a crescent-shaped intensity profile. Rotation of the plane of polarisation produces the unique effect of spatially moving the crescent-shaped beam around a ring. We use this effect to trap microspheres and white blood cells and to position them at any angular position on the ring. Continuous motion around the circle is also demonstrated. This crescent beam does not require an interferometeric arrangement to form it, nor does it carry optical angular momentum. The ability to spatially locate a beam and an associated trapped object simply by varying the polarisation of light suggests that this optical process should find application in the manipulation and actuation of micro- and nano-scale physical and biological objects.
ISSN:1094-4087
1094-4087
DOI:10.1364/OE.18.027319