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Yakir Hadad Yarden Mazor Ben Z. Steinberg

Enhanced Non-Reciprocity by Rotations I nterplay: One-Way Plasmonic Chains and Perfectly Matched Nano-Antennas. Yakir Hadad Yarden Mazor Ben Z. Steinberg. Ben Z. Steinberg. Activity Overview. Particles based plasmonic nano -structures

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Yakir Hadad Yarden Mazor Ben Z. Steinberg

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  1. Enhanced Non-Reciprocity by Rotations Interplay:One-Way Plasmonic ChainsandPerfectly Matched Nano-Antennas Yakir Hadad Yarden Mazor Ben Z. Steinberg Ben Z. Steinberg

  2. Activity Overview • Particles based plasmonicnano-structures • Particle arrays, clusters, arrays of clusters, etc.. • Symmetry breaking effects [1,4] • Non-reciprocal waveguides, one-way guiding effects • Gain and SHG in plasmonicchains [2] • Non-linear effects based on Lorentz force – gain and SHG • Chain & particles design to achieve phase-matching conditions between chain modes • Rigorous spectral analysis & Green’s function theories [3] • New wave constituents • Edge effects (finite, semi-infinite chains) • better understanding of the above, etc.. [1] Hadad , Steinberg, PRL 105 233904 (2010) [2] Steinberg, OpEx, in press [3] Hadad , Steinberg, PRB 84 125402 (2011) [4] Mazor, Steinberg, in preparation Hadad, Mazor, Steinberg

  3. Talk Overview • Strongly non-reciprocal nano-scale Plasmonic chains • Enhanced non-reciprocity by interplay of two-type rotations • Two NANO SCALE one-way waveguides: • First: Spiral structure (Chirality) • Longitudinal Magnetization leads to Faraday Rotation • Structural chirality • Second: New type of “longitudinal rotation” + “longitudinal chirality” • Use as perfectly matched Nano-Antenna • Advantages over existing one-way waveguides: • Truly nano-scale transverse dimensions • Much weaker magnetic fields [1] Hadad , Steinberg, PRL 105 233904 (2010) Hadad, Mazor, Steinberg

  4. Sub-Diffraction Chain (SDC) • Linear array of closely spaced (plasmonic) particles • Particles are much smaller than • Single particle dynamics: well described by its polarizability • -th particle excitation: dipole moment • Entire chain dynamics: Field in the absence of the particle Hadad, Mazor, Steinberg

  5. Sub-Diffraction Chain (SDC) • Chain modes • One longitudinal (z), two transverse (x,y) (trans. are degenerate if particles are spheres) • “trapped” (guided) modes: Inter-particle distance • Guided modes transverse width (if ) • Radiation modes (or leaky waves) • Traditional solution: substitute into the chain equation • With conventional plasmonic particles: reciprocal solution (even in , etc…) Hadad, Mazor, Steinberg

  6. Conventional SDC’s (Cont.) • Dispersion curves for guided modes spherical particles, • even in • Longitudinal modes bandwidth is larger by • T and L modes have the same central frequency Transverse (x,y) polarization Longitudinal (z) polarization Light-line modes Very close to light-line, down to origin (no cutoff) Very week interaction with chain Poor confinement Hardly excited (can be proved rigorously) Hadad, Mazor, Steinberg

  7. Non Reciprocal Chains • Goal: A truly nano-scale one-way waveguide • General approach: • Start with a SDC • Add longitudinal magnetic field; Faraday rotation is created (as always with magnetized plasma) – a “slight” non-reciprocity • Break spherical symmetry of plasmonic particles (e.g. use ellipsoids) • Add chirality – let the ellipsoids rotate, so a spiral is created • Interplay of two-type rotations: strong non-reciprocity, one-way guiding • Clear physical interpretation ? Y! a needle = polarizer Hadad, Mazor, Steinberg

  8. Analysis • Reference particle polarizability • (blue ellipsoid at the origin) • Where • and where • = plasma frequency, = cyclotron frequency that of a magnetized plasma Hadad, Mazor, Steinberg

  9. Analysis – Chain dynamics • Polarizability of the n-th ellipsoid • Hence chain dynamics is governed by • use matrix properties • Shift invariant difference equation for . The solution is • where Depends only on n-m Hadad, Mazor, Steinberg

  10. Results • A chain of plasmonic prolate ellipsoids with • Dispersions • Prolates have two different major axes – two different operation bands • Upper band Hadad, Mazor, Steinberg

  11. Results (Cont.) • The one-way behavior • A chain of 801 particles • Central particle (at origin) is excited Lower band Upper band Hadad, Mazor, Steinberg

  12. Fabrication – similar structure fabricated for different application [5] • Twin twisted chains of metal cylinders [5] Walavalkar, Homyk, Henry, Scherer , J. App. Phys 107, 124314 (2010) Hadad , Mazor Steinberg

  13. Yet another one (easier to fabricate, difficult to analyze) • Start with a SDC • Add transversemagnetic field: • It couples the previously independent (x,z) polarizations • a “slight” non-reciprocity: Longitudinal rotation of dipoles (rotate in a plane parallel to chain) • Break spherical symmetry of plasmonic particles (e.g. use ellipsoids) • Add longitudinal chirality– let the ellipsoids rotate, in a plane parallel to the chain • A new kind of structure • Non-Bravais lattice, or clustered chain • Can be fabricated by printing • Interplay of two-type rotations: strong non-reciprocity, one-way guiding Hadad, Mazor, Steinberg

  14. The heart of the matter – a longitudinally rotating wave • Already at the level of spherical particles with transverse H: • Longitudinal rotation – polarization rotates in a plane parallel to chain Hadad, Mazor, Steinberg

  15. Add longitudinal rotation of geometry • Response to excitation of central dipole:

  16. Analysis – Chain dynamics • Polarizability of the n-th ellipsoid • Chain dynamics is governed by • Rotation and propagation now do not commute: • Formulation is NOT shift-invariant • Need to develop and apply a theory for clustered chain (non-Bravais lattices). Hadad, Mazor, Steinberg

  17. Perfectly matched nano-antenna Leaky wave Ant. • New antenna concept • Terminated one-way waveguide • Back reflections cannot occur • Trapped mode in the “permitted” direction is converted to radiation with nearly 100% efficiency • TL in the “permitted” direction • Leaky Wave antenna in the “forbidden” direction (but broadside and not endfire) In/Output port Hadad, Mazor, Steinberg

  18. Matching results Input port How well is the port matched to chain? How well is the antenna matched? Input power Return Loss One way bandwidth Hadad, Mazor, Steinberg

  19. Radiation Patterns - Tx and Rx Main lobe • Gain – with respect to a Single Dipole (First chain’s element) • Tx mode • Rx mode • For the non-reciprocal case • Tx and Rx patterns are different One-way Two-way At the chain termination Two way: [3] Trapped Trapped One way: Trapped Leaky [3] Hadad, Steinberg, Phys Rev B 84, 125402 (2011) Hadad, Mazor, Steinberg

  20. Beam scanning • 18% variation of - • Doesn't change the one-way property • Yields turn of main lobe TX RX Hadad, Mazor, Steinberg

  21. Chiral non-reciprocal surfaces Array of magnetized spiral chains ..and if shifted: Spiral rotation chains in x (one-way) Longitudinal in y (also one-way) One-side plate One-quadrant plate ?

  22. Conclusions • Nano-scale one-way guiding : interaction between electromagnetic and geometric rotations • Nano-antennas based on these structures are: • Perfectly matched to a remote source • Non-reciprocal (different Tx Rx patterns) • Dynamically tunable (by change of magnetic field) • Advantages over existing one-way waveguides: • Truly nano-scale transverse dimensions • Much weaker magnetic fields

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