Directional and Singular Surface Plasmon Generation in Chiral and Achiral Nanostructures Demonstrated by Leakage Radiation Microscopy

Jiang, Quanbo; Pham, Aline; Berthel, Martin; Huant, S.; Bellessa, J.; Genet, Cyriaque; Drezet, Aurélien

doi:10.1021/acsphotonics.6b00197

Cited by 44 publications

(36 citation statements)

References 39 publications

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“…It is possible to achieve polarizers with high extinction ratio with help of the polarization‐selective property of SPPs and anisotropic scatterers. Polarization‐sensitive plasmonic devices, which show large controllability with high contrast, are successfully demonstrated, directional launching and switching of SPPs, multiplexed plasmonic lenses, polarization‐controlled resonators, SPP beam steering, and caustic beam generation, for instances. Other reports of polarization generators and converters, optical routers, and multiplexed holography show strong potential for wide variety of applications.…”

Section: Modeling and Designmentioning

confidence: 99%

Ultracompact Broadband Plasmonic Polarimeter

Lee

Yun

Mun

et al. 2018

Laser & Photonics Reviews

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Polarization is one of the fundamental properties of light, which is inherited from the vectorial nature of electromagnetic waves. Measuring states of polarizations (SOPs) is widely used for remote sensing applications. A number of ultracompact polarimeters that analyze SOPs at a single detection without splitting of incident beams have been demonstrated recently. However, the development of a broadband polarimeter remains challenging due to the resonant feature of their building blocks. Here, an ultracompact polarimeter that retrieves the SOP of incident light with broad operation bandwidth at near-infrared wavelengths is proposed. Surface plasmon polaritons (SPPs) excited by X-shaped aperture arrays are utilized as intensity probes. Full-Stokes parameters are retrieved by detecting the SPP intensities. The proposed polarimeter is demonstrated experimentally and can measure SOPs at wavelengths from 750 nm to 1050 nm. This work can help to develop more compact polarization-sensitive optical systems, such as polarimetry, ellipsometry, and optical routers.

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Section: Modeling and Designmentioning

confidence: 99%

Ultracompact Broadband Plasmonic Polarimeter

Lee

Yun

Mun

et al. 2018

Laser & Photonics Reviews

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“…This approach rigorously involves the nonparaxial light propagation and geometrical aberration in the microscope, which have to be considered for an accurate description of the imaging process [27,28]. To simulate the reversible SH effect for a metasurface formed by an array of 4 × 4 nanoantennas, we thus consider 16 pairs of orthogonal in-plane dipoles (oriented perpendicularly to each arm of the -shaped antennas) and coherently sum their electric fields as a function of the imaging direction [10,20,29]. The interactions between each dipole are fairly neglected as assumed in [29].…”

Section: -4mentioning

confidence: 99%

“…The spin Hall (SH) effect [3][4][5][6], which couples the internal momentum of light to its orbital angular momentum, can be applied to tune the scattering of a nanoparticle towards a confined propagating wave [7]. This type of SH effect has been reported for surface plasmon polaritons and guided waves [7][8][9][10][11]. The spin manipulation of guided modes is of particular interest for integrated optics [12], quantum optics [13], optoelectronics, biosensors [14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Metasurface for Reciprocal Spin-Orbit Coupling of Light on Waveguiding Structures

et al. 2018

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Light manipulation through spin-orbit coupling opens new perspectives in photonics and particularly in integrated optics. The reverse spin Hall effect, where the guided wave direction affects the polarization properties of the light scattered by a nanostructure, is a key effect for the development of new functionalities at the connection between integrated structures and free space, and could find application in chiral quantum optics, modulation, and multiplexing. We show that metasurfaces represent a promising platform for the reverse spin Hall effect. Using a periodic array of-shaped metallic nanoantenna, we control the polarization of the extracted light with the guided wave-propagation direction, but also the number of output directions and the polarization of each one. These results and the versatility of metasurfaces for the spin Hall effect could be extended to various frequencies and materials, such as silicon photonics at telecom wavelength.

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“…However, this approach can be hardly adopted when the input field has a limited spatial extension (as for focused beams or localized coherent sources such as optical antennas or cavities), unless some mode coupling is intervening [25]. This is indeed the case in structured metallic films, wherein the generation of free-space vortex beam carrying OAM occurs upon spin-orbit coupling and scattering/diffraction of plasmonic modes by means of nano-slits [26][27][28], properly arranged nano-apertures [29], possibly combined with circular diffraction gratings [30,31]. Such results rely on the fact that OAM possessed by surface plasmons can be further manipulated and transferred to freely propagating radiation [28,32].…”

Section: Introductionmentioning

confidence: 99%

Vortex Beam Generation by Spin-Orbit Interaction with Bloch Surface Waves

et al. 2020

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Axis-symmetric grooves milled in metallic slabs have been demonstrated to promote the transfer of Orbital Angular Momentum (OAM) from far- to near-field and vice versa, thanks to spin-orbit coupling effects involving Surface Plasmons (SP). However, the high absorption losses and the polarization constraints, which are intrinsic in plasmonic structures, limit their effectiveness for applications in the visible spectrum, particularly if emitters located in close proximity to the metallic surface are concerned. Here, an alternative mechanism for vortex beam generation is presented, wherein a free-space radiation possessing OAM is obtained by diffraction of Bloch Surface Waves (BSWs) on a dielectric multilayer. A circularly polarized laser beam is tightly focused on the multilayer surface by means of an immersion optics, such that TE-polarized BSWs are launched radially from the focused spot. While propagating on the multilayer surface, BSWs exhibit a spiral-like wavefront due to the Spin-Orbit Interaction (SOI). A spiral grating surrounding the illumination area provides for the BSW diffraction out-of-plane and imparts an additional azimuthal geometric phase distribution defined by the topological charge of the spiral structure. At infinity, the constructive interference results into free-space beams with defined combinations of polarization and OAM satisfying the conservation of the Total Angular Momentum, based on the incident polarization handedness and the spiral grating topological charge. As an extension of this concept, chiral diffractive structures for BSWs can be used in combination with surface cavities hosting light sources therein.

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Directional and Singular Surface Plasmon Generation in Chiral and Achiral Nanostructures Demonstrated by Leakage Radiation Microscopy

Cited by 44 publications

References 39 publications

Ultracompact Broadband Plasmonic Polarimeter

Ultracompact Broadband Plasmonic Polarimeter

Metasurface for Reciprocal Spin-Orbit Coupling of Light on Waveguiding Structures

Vortex Beam Generation by Spin-Orbit Interaction with Bloch Surface Waves

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