Abstract
In search of new technologies for optimizing the performance and space requirements of electronic and optical micro-circuits, the concept of spoof surface plasmon polaritons (SSPPs) has come to the fore of research in recent years. Due to the ability of SSPPs to confine and guide the energy of electromagnetic waves in a subwavelength space below the diffraction limit, SSPPs deliver all the tools to implement integrated circuits with a high integration rate. However, in order to guide SSPPs in the terahertz frequency range, it is necessary to carefully design metasurfaces that allow one to manipulate the spatio-temporal and spectral properties of the SSPPs at will. Here, we propose a specifically designed cut-wire metasurface that sustains strongly confined SSPP modes at terahertz frequencies. As we show by numerical simulations and also prove in experimental measurements, the proposed metasurface can tightly guide SSPPs on straight and curved pathways while maintaining their subwavelength field confinement perpendicular to the surface. Furthermore, we investigate the dependence of the spatio-temporal and spectral properties of the SSPP modes on the width of the metasurface lanes that can be composed of one, two or three cut-wires in the transverse direction. Our investigations deliver new insights into downsizing effects of guiding structures for SSPPs.
Highlights
Modern electronic devices contain a variety of miniaturized sensors and signal processing units that are based on integrated circuit technologies
We studied the propagation of strongly confined terahertz surface plasmon polaritons (SSPPs) along straight and curved pathways of subwavelength width on designed metasurfaces
We numerically calculated the dispersion of the spoof surface plasmon polaritons (SSPPs) mode and simulated the propagating electromagnetic fields of the SSPPs on the metasurfaces
Summary
Modern electronic devices contain a variety of miniaturized sensors and signal processing units that are based on integrated circuit technologies. In highly integrated circuits it is mandatory that the metasurface structures confine the SSPPs within the plane of propagation on a subwavelength scale and allow deliberate waveguiding and routing of the SSPPs on pathways with subwavelength path width In this context, latest research that covers such flat and compact sized metasurface structures at terahertz frequencies lack experimental evaluation [20,21,22]. They are either restricted to numerical simulation models [20,22] or they only deliver simple proof-in-principle demonstrations in the microwave regime [21] For this reason, it was our goal to design and fabricate ultrathin metasurfaces with tailored dispersion to gain full control over the in-plane propagation of terahertz SSPPs, while still maintaining a subwavelength field confinement to the metasurface. We limited the width of the metasurface pathway to a small number of cut-wire unit cells and found that the number of unit cells transverse to the propagation direction of the surface waves has a strong influence on the spectral bandwidth of the supported SSPP mode
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