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Intrinsic spin-momentum dynamics of surface electromagnetic waves in complex dispersive system

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arxiv 2202.09007 v1 pith:ET3QB6RZ submitted 2022-02-18 physics.optics

Intrinsic spin-momentum dynamics of surface electromagnetic waves in complex dispersive system

classification physics.optics
keywords spin-momentumlockingdispersivespinsurfacedispersiondiverseelectromagnetic
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Spin-momentum locking is an intrinsic property of surface electromagnetic fields and its study has led to the discovery of photonic spin lattices and diverse applications. Previously, dispersion was ignored in the spin-momentum locking, giving rise to abnormal phenomena contradictory to the physical realities. Here, we formulate four dispersive spin-momentum equations for surface waves, revealing universally that the transverse spin vector is locked with the momentum. The locking property obeys the right-hand rule in the dielectric but the left-hand rule in the dispersive metal/magnetic materials. In addition to the dispersion, the structural features can affect the spin-momentum locking significantly. Remarkably, an extraordinary longitudinal spin originating from the coupling polarization ellipticity is uncovered even for the purely polarized state. We further demonstrate the spin-momentum locking properties with diverse photonic topological lattices by engineering the rotating symmetry. The findings open up opportunities for designing robust nanodevices with practical importance in chiral quantum optics.

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