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Main Authors: Permana, Dharma P., Sinkevičienė, Mažena Mackoit, Ruseckas, Julius, Hamedi, Hamid R.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.23097
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_version_ 1866909051382661120
author Permana, Dharma P.
Sinkevičienė, Mažena Mackoit
Ruseckas, Julius
Hamedi, Hamid R.
author_facet Permana, Dharma P.
Sinkevičienė, Mažena Mackoit
Ruseckas, Julius
Hamedi, Hamid R.
contents We investigate the propagation of optical vector vortices of slow light in a coherently prepared four-level tripod atomic system. The vector vortex consists of superposed pulse pairs with opposite circular polarizations and orbital angular momentum (OAM) charges $\pm l$, weakly interacting with an atomic medium initially prepared in a coherent superposition of two ground states. A third unoccupied state is coupled to a stronger control laser without OAM, creating a phase-dependent configuration. In the linear regime, the vortex OAM is mapped onto the medium, producing symmetrical azimuthally structured absorption patterns, with losses significantly reduced by the control field. For small detunings, complementary spatially dependent amplification and absorption occur for the two circular polarization components. This OAM-structured coherence induces a dynamical anisotropy, affecting both the intensity and polarization of the slow-light vortex. Polarization states evolve periodically between left-circular, linear, and right-circular polarizations during propagation. Once the beam reaches a stationary regime, the ring-shaped intensity transforms into a petal-like structure, and the final polarization states stabilize according to the initial superposition. The rate of polarization transitions is tunable via the control field strength, demonstrating flexible control over slow-light vector vortex dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2603_23097
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Propagation of optical vector vortices of slow light in a coherently prepared tripod configuration
Permana, Dharma P.
Sinkevičienė, Mažena Mackoit
Ruseckas, Julius
Hamedi, Hamid R.
Quantum Physics
We investigate the propagation of optical vector vortices of slow light in a coherently prepared four-level tripod atomic system. The vector vortex consists of superposed pulse pairs with opposite circular polarizations and orbital angular momentum (OAM) charges $\pm l$, weakly interacting with an atomic medium initially prepared in a coherent superposition of two ground states. A third unoccupied state is coupled to a stronger control laser without OAM, creating a phase-dependent configuration. In the linear regime, the vortex OAM is mapped onto the medium, producing symmetrical azimuthally structured absorption patterns, with losses significantly reduced by the control field. For small detunings, complementary spatially dependent amplification and absorption occur for the two circular polarization components. This OAM-structured coherence induces a dynamical anisotropy, affecting both the intensity and polarization of the slow-light vortex. Polarization states evolve periodically between left-circular, linear, and right-circular polarizations during propagation. Once the beam reaches a stationary regime, the ring-shaped intensity transforms into a petal-like structure, and the final polarization states stabilize according to the initial superposition. The rate of polarization transitions is tunable via the control field strength, demonstrating flexible control over slow-light vector vortex dynamics.
title Propagation of optical vector vortices of slow light in a coherently prepared tripod configuration
topic Quantum Physics
url https://arxiv.org/abs/2603.23097