Maayan Fox scite author profile

Maayan Fox

5Publications

16Citation Statements Received

246Citation Statements Given

How they've been cited

How they cite others

203

245

Affiliations

Ariel University

Publications

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Generalized approach to plasmonic phase modulation in topological bi-gratings

Fox

Gorodetski

2022

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We study the role of optical momenta in surface plasmon excitation by topological bi-gratings. We analyze plasmonic structures composed of rectangular apertures rotating in 2D space with given rates, which couple to specific plasmon trajectories. We experimentally demonstrate the control of plasmonic propagation through premeditated design of the gratings, which interact with linear, spin, and orbital angular momentum of light. We show that these trajectories can be selected purely through momenta modulation with numerous degrees of freedom for a given structure geometry. Moreover, it is shown that the symmetry of the final plasmonic distribution is defined by selecting specific rotation rates, and that it can be different from the original grating symmetry.

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Topological Dislocations for Plasmonic Mode Localization in Arrays of Nanoscale Rectangular Au Apertures: Implications for Optical Communications

Epstein

Singh

Fox

et al. 2021

ACS Appl. Nano Mater.

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We study the localization of plasmonic modes on topological dislocations obtained by an abrupt change in the geometry of unit cells in a plasmonic metasurface comprised of a nanoscale array of rectangular apertures. We experimentally demonstrate mode localization in line defects and point singularities in the topology. These results are confirmed by numerical simulations of the near field distributions along the topology boundaries. We present structures with line dislocations supporting dark and bright modes. Moreover, we show that in structures with point dislocations the localization strength can be further manipulated by modifying the topological order of the structure.

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Topological Diffraction from Grating with Space Variant Chirality

et al. 2022

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Light–matter interactions in a chiral structure can induce strong polarization selectivity. Specifically, an optical activity in a form of polarization rotation and a circular dichroism may be controlled by the mirror symmetry breaking of the unit-cell geometry. We design and experimentally investigate plasmonic metasurfaces with a spatially varying chiral geometry and demonstrate how this architecture may lead to a geometric Berry phase. Our designed structure produces a polarization-dependent diffraction of nearly linear states. We experimentally examine the diffraction orders and show that they are topological in nature. Moreover, the influence of various geometrical factors is also investigated.

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Topologically protected plasmonic phases in randomized aperture gratings

Fox

Gorodetski

2023

Sci Rep

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We experimentally show the excitation of surface plasmons by topologically protected diffraction from gratings with randomized periodicity. The structures are designed such that the plasmonic excitation is conditioned by the proper combination of the geometric and the dynamic phases. Accordingly, it is possible to obtain a precise interaction of the incident light signal and a specific plasmonic directional mode in a polarization dependent manner.

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Topological dislocations for plasmonic mode localization

Epstein¹,

Singh²,

Fox³

et al. 2020

Preprint

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We study the localization of plasmonic modes on topological dislocations obtained by an abrupt change in the geometry of unit-cells in a plasmonic metasurface. We experimentally demonstrate mode localization in line defects and point singularities in the topology. These results are confirmed by numerical simulations of the near field distributions along the topology boundaries. We present structures with line dislocations supporting dark and bright modes. Moreover, we show that in structures with point dislocations the localization strength can be further manipulated by modifying the topological order of the structure.

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Maayan Fox

Generalized approach to plasmonic phase modulation in topological bi-gratings

Topological Dislocations for Plasmonic Mode Localization in Arrays of Nanoscale Rectangular Au Apertures: Implications for Optical Communications

Topological Diffraction from Grating with Space Variant Chirality

Topologically protected plasmonic phases in randomized aperture gratings

Topological dislocations for plasmonic mode localization

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