Gravitational orbital Hall effect of vortex light in Lense–Thirring metric

Vortex light, characterized by an intrinsic orbital angular momentum aligned with its propagation direction, is described through vortex electromagnetic waves. Similar to the gravitational spin Hall effect (SHE), vortex light is expected to exhibit intrinsic orbital angular momentum dependent trajec...

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Bibliographic Details
Published in:The European physical journal. C, Particles and fields Particles and fields, 2024-10, Vol.84 (10), p.1013-11, Article 1013
Main Authors: Qiu, Wei-Si, Lian, Dan-Dan, Zhang, Peng-Ming
Format: Article
Language:English
Subjects:
Angular momentum
Astronomy
Astrophysics and Cosmology
Deviation
Electromagnetic radiation
Electromagnetism
Elementary Particles
Gravitational fields
Hadrons
Hall effect
Heavy Ions
Light
Maxwell's equations
Measurement Science and Instrumentation
Nuclear Energy
Nuclear Physics
Physics
Physics and Astronomy
Polarized light
Quantum Field Theories
Quantum Field Theory
Regular Article - Theoretical Physics
String Theory
Trajectories
Vortices
Wave packets
Wave propagation
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Summary:Vortex light, characterized by an intrinsic orbital angular momentum aligned with its propagation direction, is described through vortex electromagnetic waves. Similar to the gravitational spin Hall effect (SHE), vortex light is expected to exhibit intrinsic orbital angular momentum dependent trajectories and deviations from the null geodesic plane when propagating through a gravitational field, a phenomenon termed the gravitational orbital Hall effect (OHE). In this work, we model the vortex light as vortex Laguerre–Gaussian electromagnetic wave packets and analyze its motion by solving covariant Maxwell equations within the Lense–Thirring metric. Our findings reveal that the trajectory of vortex light with an intrinsic orbital angular momentum deviates from the null geodesic in two ways. It deviates both perpendicular to, and within, the null geodesic plane. This behavior contrasts with the gravitational SHE, where spin-polarized light primarily deviates perpendicular to the null geodesic plane. Moreover, the relationship between the deviation and intrinsic orbital angular momentum differs significantly from that between the deviation and spin. These results suggest a unique interaction between intrinsic orbital angular momentum and gravity, distinct from the spin-gravity coupling, indicating that the gravitational OHE of light might not be precisely predicted by merely substituting spin with intrinsic orbital angular momentum in the gravitational SHE of light.
ISSN:1434-6052
1434-6044
1434-6052
DOI:10.1140/epjc/s10052-024-13409-x