Litcius/Paper detail

Transfer and evolution of structured polarization in a double-V atomic system

Zhenzhu Li, Sonja Franke‐Arnold, Thomas W. Clark, Jinwen Wang, Dawei Zhang, Chunfang Wang

2022Optics Express11 citationsDOIOpen Access PDF

Abstract

We numerically investigate the transfer of optical information from a vector-vortex control beam to an unstructured probe beam, as mediated by an atomic vapour. The right and left circular components of these beams drive the atomic transitions of a double-V system, with the atoms acting as a spatially varying circular birefringent medium. Modeling the propagation of the light fields, we find that, for short distances, the vectorial light structure is transferred from the control field to the probe. However, for larger propagation lengths, diffraction causes the circular components of the probe field to spatially separate. We model this system for the D1 line of cold rubidium atoms and demonstrate that four wave mixing can lead to correlations between the optical polarization structure and the diffraction of light, generating coupled dynamics of the internal and external degrees of freedom.

Topics & Concepts

OpticsRubidiumPolarization (electrochemistry)PhysicsDiffractionCircular polarizationLight beamOptical vortexBirefringenceAtomic coherenceBeam (structure)Light fieldElectromagnetically induced transparencyAtomic physicsMaterials scienceLaserChemistryMetallurgyMicrostripPhysical chemistryPotassiumQuantum optics and atomic interactionsCold Atom Physics and Bose-Einstein CondensatesOrbital Angular Momentum in Optics