2022
DOI: 10.1140/epjp/s13360-022-02800-w
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A novel plasmonic waveguide for the dual-band transmission of spoof surface plasmon polaritons

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Cited by 9 publications
(4 citation statements)
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“…The 1D waveguide consists of a series of coupled resonators in which light propagates due to the coupling between the adjacent resonators (see figure 1(a)). The system can be implemented by nano-electromechanical resonator arrays where two nearest resonators with ferromagnetic particles in the tips are coupled to a localized spin [47], a side-defected cavity with double couplings to a waveguide of coupled defected cavity arrays [25,48,49], a superconducting atoms coupled to a Josephson photonic-crystal waveguide [46,50], or a quantum emitter coupled to a surface plasmon polartion waveguide [51,52]. For the last system the surface plasmon polartion supported by a metallic waveguide and can be strongly coupled with quantum emitter [53,54] and the dual-band surface polariton waveguide can be realized by composite structures, which facilitates the emergence of the bound states.…”
Section: Model For a Quantum Emitter Nonlocal Coupled To A Dimer Chainmentioning
confidence: 99%
“…The 1D waveguide consists of a series of coupled resonators in which light propagates due to the coupling between the adjacent resonators (see figure 1(a)). The system can be implemented by nano-electromechanical resonator arrays where two nearest resonators with ferromagnetic particles in the tips are coupled to a localized spin [47], a side-defected cavity with double couplings to a waveguide of coupled defected cavity arrays [25,48,49], a superconducting atoms coupled to a Josephson photonic-crystal waveguide [46,50], or a quantum emitter coupled to a surface plasmon polartion waveguide [51,52]. For the last system the surface plasmon polartion supported by a metallic waveguide and can be strongly coupled with quantum emitter [53,54] and the dual-band surface polariton waveguide can be realized by composite structures, which facilitates the emergence of the bound states.…”
Section: Model For a Quantum Emitter Nonlocal Coupled To A Dimer Chainmentioning
confidence: 99%
“…conductors, which are extremely unsuitable conditions for the excitation of SPP waves. To solve this problem, plasmonic metamaterials have been proposed to realize spoof SPPs (SSPPs) [7][8][9][10][11][12][13][14][15][16][17][18][19][20], which are highly capable of confining electromagnetic (EM) waves at microwave and terahertz frequencies. Moreover, dispersion properties and spatial confinement of SSPPs can be handled very efficiently by the structural parameters of a plasmonic waveguide, which is a huge advantage related to metamaterials.…”
Section: Introductionmentioning
confidence: 99%
“…In the beginning, the SSPPs' supporting structures are in bulk form because of recognition of the convenience of achieving analytic solutions, and this is not practically implementable in planar circuitry. Accordingly, many SPP devices have been reported and verified by matching their compatibility with conventional planar circuitry [15][16][17][18][19][20][21][22][23][24][25][26][27]. Moreover, SPP wave-based systems have unique advantages, for example, lowering the loss of dielectrics [28], overcoming the challenges in maintaining the signal integrity [29], lessening the shielding box size [30] and bending-loss reduction [31].…”
Section: Introductionmentioning
confidence: 99%