Energy Backflow in Tightly Focused Fractional Order Vector Vortex Beams with Binary Topological Charges

Wu, Yan; Hu, Xiao-Bo; Li, Yuhua; Chen, Rui-Pin

doi:10.3390/photonics10070820

Photonics

2023

DOI: 10.3390/photonics10070820

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Energy Backflow in Tightly Focused Fractional Order Vector Vortex Beams with Binary Topological Charges

Yan Wu

Xiao-Bo Hu

Yuhua Li

et al.

Abstract: Using the Richards–Wolf diffraction integral, the longitudinal energy evolution on the focal plane of the fractional order vector vortex (FOVV) beams was studied. These beams possessed a vortex topological charge n and a polarization topological charge m, and were subjected to tight focusing through a larger numerical aperture. Our investigation revealed the existence of backflow energy when the binary topological charges n and m satisfied the conditions of n + m = 2 or n − m = −2. The component circularly pol… Show more

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2024

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Cited by 2 publications

References 22 publications

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Orbital angular momentum at the tight focus of a circularly polarized Gaussian beam

Kotlyar,

Kovalev,

Stafeev

et al. 2024

J. Opt. Soc. Am. A

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When tightly focusing a circularly polarized optical vortex, a phenomenon of spin-to-orbit conversion has been known to occur. As a rule, the longitudinal component of the spin angular momentum (SAM) vector is assumed to be converted into the longitudinal component of the orbital angular momentum (OAM) vector. In this work, we show that, due to the focusing, the original longitudinal SAM component, averaged over the beam cross-section, is partly converted to the transverse SAM component. In a similar way, the original longitudinal energy flow is partly converted, upon focusing, to the azimuthal component. Meanwhile, the longitudinal component of the OAM vector, averaged over the entire beam cross-section at the focus, increases exactly by the magnitude of the (canonical) averaged azimuthal orbital energy flow at the focus. We show that, upon focusing, the azimuthal energy flow is formed at the focus due to the fact that a right-handed circularly polarized light wave generates two optical vortices: a transverse left-handed circularly polarized vortex with topological charge 2 and a longitudinal vortex with topological charge 1.

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Orbital angular momentum at the tight focus of a circularly polarized Gaussian beam

Kotlyar,

Kovalev,

Stafeev

et al. 2024

J. Opt. Soc. Am. A

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show abstract

Transverse and Longitudinal Energy Flows in a Sharp Focus of Vortex and Cylindrical Vector Beams

Kotlyar,

Kovalev,

Nalimov

et al. 2024

Applied Sciences

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It is shown in this work that, with strong focusing of a beam with optical vortex and circular polarization, three energy flows take place in the focal plane: direct longitudinal, reverse longitudinal and azimuthal transverse flows. Calculations are made analytically using the Richards–Wolf formalism and by numerical simulation. Moreover, the energy rotation at different lengths from the optical axis occurs in different directions. Therefore, the focal plane intersects along the optical axis only part of the initial beam energy per unit time. The same energy part (other things being equal) intersects the focal plane along the positive direction of the optical axis when an optical vortex with cylindrical polarization is focused. The difference is that, if an optical vortex is present, then the transverse energy flux at the focus rotates around the optical axis. If an optical vortex is not present (a beam with only cylindrical polarization), then the average transverse flow in the focal plane is zero, though, in some regions in the focal plane, the flow is directed towards the optical axis and, in other regions, away from it. This behavior of the transverse energy flow at the focus (flow direction towards the optical axis and away from the optical axis) of a cylindrical vector beam can be deemed another kind of Hall effect.

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Energy Backflow in Tightly Focused Fractional Order Vector Vortex Beams with Binary Topological Charges

Cited by 2 publications

References 22 publications

Orbital angular momentum at the tight focus of a circularly polarized Gaussian beam

Orbital angular momentum at the tight focus of a circularly polarized Gaussian beam

Transverse and Longitudinal Energy Flows in a Sharp Focus of Vortex and Cylindrical Vector Beams

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