AI Article Synopsis
- The authors propose a novel topological plasmonic crystal made of an array of nanowires with varying spacing to effectively manipulate light.
- The light propagation in this setup can be mathematically represented by the Su-Schrieffer-Heeger model, indicating a link between optics and quantum mechanics.
- The study confirms the presence of localized defect modes in the crystal, allowing for advanced applications like spatial mode filters and beam-splitters, and reveals that these structures remain functional even with minor fabrication errors.
Article Abstract
We propose using a topological plasmonic crystal structure composed of an array of nearly parallel nanowires with unequal spacing for manipulating light. In the paraxial approximation, the Helmholtz equation that describes the propagation of light along the nanowires maps onto the Schrödinger equation of the Su-Schrieffer-Heeger (SSH) model. Using a full three-dimensional finite difference time domain solution of the Maxwell equations, we verify the existence of topological defect modes, with sub-wavelength localization, bound to domain walls of the plasmonic crystal. We show that by manipulating domain walls we can construct spatial mode filters that couple bulk modes to topological defect modes, and topological beam-splitters that couple two topological defect modes. Finally, we show that the structures are tolerant to fabrication errors with an inverse length-scale smaller than the topological band gap.
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| http://dx.doi.org/10.1364/OE.26.002857 | DOI Listing |
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