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Unified approach towards the dynamics of optical and electron vortex beams

We have proposed a unified framework towards the dynamics of optical and electron vortex beams from the perspective of geometric phase and the associated Hall effects. The unification is attributed to the notion that the spin degrees of freedom of a relativistic particle, either massive or massless, is associated with a vortex line. %The formulation in cylindrical coordinates leads to a local vortex structure related to orbital angular momentum(OAM). Based on cylindrical corodinate formulation, which leads to a local vortex structure related to orbital angular momentum (OAM), it can be shown that when electron vortex beams (EVBs) move in an external electric field paraxial beams give rise to OAM Hall effect and non-paraxial beams with tilted vortices initiate spin Hall effect in free space as well as in an external field. A similar analysis reveals that the paraxial optical vortex beams(OVBs) in an inhomogeneous medium induce OAM Hall effect whereas non-paraxial beams with tilted vortices drive the spin Hall effect. Moreover, both OVBs and EVBs with tilted vortices give rise to OAM states with arbitrary fractional value.

preprint2016arXivOpen access
Pratul BandyopadhyayBanasri BasuDebashree Chowdhury
cond-mat.mes-hallphysics.opticsquant-ph
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Pratul BandyopadhyayBanasri BasuDebashree Chowdhury

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