Arbitrary Polarization Syntheses Based on Spin‐Momentum Locking in Spoof Surface Plasmon Polaritons

Spin‐momentum locking is universal and an inherent property of evanescent electromagnetic (EM) waves, which transfers the spinning or handedness of electromagnetic waves onto their propagation direction. This motivates an approach to investigate the polarization‐controlled directional transmission or emission. Here, the spin‐momentum locking is demonstrated in spoof surface plasmon polariton (SSPP) waveguides, and momentum‐controlled radiation is further realized in SSPP‐patch antennas. The study shows that the circular polarization of the SSPP‐patch antennas originates from the spin‐momentum locking in the SSPP waveguides and hence is determined by the propagation direction of the SSPP modes. Two examples are presented to achieve ±45° dual‐polarizations and vertical/horizontal dual‐polarizations by combining the SSPP‐patch antenna with hybrid couplers. Finally, a straightforward method is proposed for synthesizing the polarization emitted by the SSPP‐patch antenna, allowing access to arbitrary polarization states on the Poincare sphere. The SSPP‐patch antenna is polarization responsive, shedding light on chiral sensors, Stokes polarimetry, and polarization measurement. Hence, the spin‐momentum locking and the related momentum‐controlled radiations provide additional freedom to regulate the EM waves by engineering the helicity in the SSPP waveguide.

[1]  Jun Feng Liu,et al.  Spin‐Controlled Reconfigurable Excitations of Spoof Surface Plasmon Polaritons by a Compact Structure , 2022, Laser & Photonics Reviews.

[2]  Hongtao Lin,et al.  Tunable narrow-band single-channel add-drop integrated optical filter with ultrawide FSR , 2022, PhotoniX.

[3]  A. High,et al.  Electrically controllable chirality in a nanophotonic interface with a two-dimensional semiconductor , 2022, Nature Photonics.

[4]  P. Palmer,et al.  Reply to: The size of the land carbon sink in China , 2022, Nature.

[5]  Yan Lu,et al.  Self-Assembly of Plasmonic Nanoantenna-Waveguide Structures for Subdiffractional Chiral Sensing. , 2020, ACS nano.

[6]  S. Zhuang,et al.  Terahertz spectroscopy in biomedical field: a review on signal-to-noise ratio improvement , 2020 .

[7]  T. Cui,et al.  Gain‐Assisted Active Spoof Plasmonic Fano Resonance for High‐Resolution Sensing of Glucose Aqueous Solutions , 2019, Advanced Materials Technologies.

[8]  Mingfeng Xu,et al.  Spoof Plasmonic Metasurfaces with Catenary Dispersion for Two-Dimensional Wide-Angle Focusing and Imaging , 2019, iScience.

[9]  Joe V. Carpenter,et al.  Nature-inspired chiral metasurfaces for circular polarization detection and full-Stokes polarimetric measurements , 2019, Light: Science & Applications.

[10]  E. Waks,et al.  A topological quantum optics interface , 2017, Science.

[11]  L. Kuipers,et al.  Nanoscale chiral valley-photon interface through optical spin-orbit coupling , 2017, Science.

[12]  Peter Zoller,et al.  Chiral quantum optics , 2016, Nature.

[13]  Shuo Liu,et al.  Information entropy of coding metasurface , 2016, Light: Science & Applications.

[14]  Gerd Leuchs,et al.  From transverse angular momentum to photonic wheels , 2015, Nature Photonics.

[15]  F. J. Rodríguez-Fortuño,et al.  Spin–orbit interactions of light , 2015, Nature Photonics.

[16]  Franco Nori,et al.  Transverse and longitudinal angular momenta of light , 2015, 1504.03113.

[17]  Qiang Cheng,et al.  Coding metamaterials, digital metamaterials and programmable metamaterials , 2014, Light: Science & Applications.

[18]  A. Rauschenbeutel,et al.  Chiral nanophotonic waveguide interface based on spin-orbit interaction of light , 2014, Science.

[19]  F. J. Rodríguez-Fortuño,et al.  Universal method for the synthesis of arbitrary polarization states radiated by a nanoantenna , 2014, 1510.01530.

[20]  Qiang Cheng,et al.  Broadband and high‐efficiency conversion from guided waves to spoof surface plasmon polaritons , 2014 .

[21]  Franco Nori,et al.  Extraordinary momentum and spin in evanescent waves , 2013, Nature Communications.

[22]  E. Hasman,et al.  Spin-Optical Metamaterial Route to Spin-Controlled Photonics , 2013, Science.

[23]  F. J. Rodríguez-Fortuño,et al.  Near-Field Interference for the Unidirectional Excitation of Electromagnetic Guided Modes , 2013, Science.

[24]  F. Capasso,et al.  Polarization-Controlled Tunable Directional Coupling of Surface Plasmon Polaritons , 2013, Science.

[25]  Tie Jun Cui,et al.  Conformal surface plasmons propagating on ultrathin and flexible films , 2012, Proceedings of the National Academy of Sciences.

[26]  Gennady Shvets,et al.  Photonic topological insulators. , 2012, Nature materials.

[27]  S. Maier Plasmonics: Fundamentals and Applications , 2007 .

[28]  A. Maradudin,et al.  Nano-optics of surface plasmon polaritons , 2005 .

[29]  J. Pendry,et al.  Surfaces with holes in them: new plasmonic metamaterials , 2005 .

[30]  J. Pendry,et al.  Mimicking Surface Plasmons with Structured Surfaces , 2004, Science.

[31]  J. Romeu,et al.  Exact representation of antenna system diversity performance from input parameter description , 2003 .

[32]  Seftya Eka Fahyan,et al.  Principles of optics : electromagnetic theory of propagation, interference and diffraction of light / by Max Born and Emil Wolf , 1992 .