Polarization-Controlled Tunable Directional Coupling of Surface Plasmon Polaritons

Lin, Jiao; Mueller, J. P. Balthasar; Wang, Qian; Yuan, Guanghui; Antoniou, Nicholas; Yuan, Xiaocong; Capasso, Federico

doi:10.1126/science.1233746

Cited by 1,116 publications

(966 citation statements)

References 77 publications

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“…[1][2][3][4][5] Noble-metal nanostructures present an excellent platform for strongly confined optical waveguides 6-13 because of their ability to support surface plasmon polaritons (SPPs). 14 However, SPP propagation suffers from losses that seriously limit their application potential.…”

Section: Subwavelength Confinement and Active Control Of Light Is Essmentioning

confidence: 99%

Dye-Assisted Gain of Strongly Confined Surface Plasmon Polaritons in Silver Nanowires

Paul

Zhen²,

Wang

et al. 2014

Nano Lett.

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Noble metal nanowires are excellent candidates as subwavelength optical components in miniaturized devices due to their ability to support the propagation of surface plasmon polaritons (SPPs). Nanoscale data transfer based on SPP propagation at optical frequencies has the advantage of larger bandwidths but also suffers from larger losses due to strong mode confinement. To overcome losses, SPP gain has been realized, but so far only for weakly confined SPPs in metal films and stripes. Here we report the demonstration of gain for subwavelength SPPs that were strongly confined in chemically prepared silver nanowires (mode area = λ2/40) using a dye-doped polymer film as the optical gain medium. Under continuous wave excitation at 514 nm, we measured a gain coefficient of 270 cm–1 for SPPs at 633 nm, resulting in partial SPP loss compensation of 14%. This achievement for strongly confined SPPs represents a major step forward toward the realization of nanoscale plasmonic amplifiers and lasers.

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Section: Subwavelength Confinement and Active Control Of Light Is Essmentioning

confidence: 99%

Dye-Assisted Gain of Strongly Confined Surface Plasmon Polaritons in Silver Nanowires

Paul

Zhen²,

Wang

et al. 2014

Nano Lett.

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“…As 2D artificially engineered structures,1, 2, 3 metasurfaces have attracted great attention in physics and engineering communities owing to a number of unique properties 4, 5, 6, 7, 8, 9, 10, 11, 12. A metasurface is formed by distributing subwavelength resonant particles with different geometries and materials on a 2D surface, and therefore is able to manipulate both amplitudes and phases of electromagnetic (EM) waves, enabling many extraordinary functionalities such as the polarization conversion,,13, 14, 15, 16, 17 perfect absorption,18, 19, 20 and amplitude and phase modulations 21, 22.…”

Section: Introductionmentioning

confidence: 99%

Convolution Operations on Coding Metasurface to Reach Flexible and Continuous Controls of Terahertz Beams

et al. 2016

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The concept of coding metasurface makes a link between physically metamaterial particles and digital codes, and hence it is possible to perform digital signal processing on the coding metasurface to realize unusual physical phenomena. Here, this study presents to perform Fourier operations on coding metasurfaces and proposes a principle called as scattering‐pattern shift using the convolution theorem, which allows steering of the scattering pattern to an arbitrarily predesigned direction. Owing to the constant reflection amplitude of coding particles, the required coding pattern can be simply achieved by the modulus of two coding matrices. This study demonstrates that the scattering patterns that are directly calculated from the coding pattern using the Fourier transform have excellent agreements to the numerical simulations based on realistic coding structures, providing an efficient method in optimizing coding patterns to achieve predesigned scattering beams. The most important advantage of this approach over the previous schemes in producing anomalous single‐beam scattering is its flexible and continuous controls to arbitrary directions. This work opens a new route to study metamaterial from a fully digital perspective, predicting the possibility of combining conventional theorems in digital signal processing with the coding metasurface to realize more powerful manipulations of electromagnetic waves.

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“…The effect is based on the reciprocity of optical interactions and the peculiar transverse angular momentum specific to surface electromagnetic waves on a metal-dielectric interface. While in the direct photonic SHE (PSHE), the polarization of the incident light controls the direction of the SPP excitation on a surface [2][3][4][5][6][7] , in the reciprocal scenario, in analogy to the spin injection current control in solidstate spintronic devices (inverse SHE) 8 , the direction of the scattered light of a given polarization is determined by the direction of the SPPs impinging at a scatterer.…”

mentioning

confidence: 99%

“…In the electronic SHE, electrons with opposite spins undertake different trajectories in a current flow 1 . In optics, photons with opposite spins-left or right circularly polarized (LCP or RCP) light-may propagate in different directions upon interaction with the material environment if spin-orbital coupling is engineered using, for example, metasurfaces [2][3][4] , Berry phase 5 , refractive index gradient 6 or near-field interference 7 .…”

mentioning

confidence: 99%

Spin–orbit coupling in surface plasmon scattering by nanostructures

et al. 2014

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The spin Hall effect leads to the separation of electrons with opposite spins in different directions perpendicular to the electric current flow because of interaction between spin and orbital angular momenta. Similarly, photons with opposite spins (different handedness of circular light polarization) may take different trajectories when interacting with metasurfaces that break spatial inversion symmetry or when the inversion symmetry is broken by the radiation of a dipole near an interface. Here we demonstrate a reciprocal effect of spin-orbit coupling when the direction of propagation of a surface plasmon wave, which intrinsically has unusual transverse spin, determines a scattering direction of spin-carrying photons. This spin-orbit coupling effect is an optical analogue of the spin injection in solid-state spintronic devices (inverse spin Hall effect) and may be important for optical information processing, quantum optical technology and topological surface metrology.

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Polarization-Controlled Tunable Directional Coupling of Surface Plasmon Polaritons

Cited by 1,116 publications

References 77 publications

Dye-Assisted Gain of Strongly Confined Surface Plasmon Polaritons in Silver Nanowires

Dye-Assisted Gain of Strongly Confined Surface Plasmon Polaritons in Silver Nanowires

Convolution Operations on Coding Metasurface to Reach Flexible and Continuous Controls of Terahertz Beams

Spin–orbit coupling in surface plasmon scattering by nanostructures

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