Mechanically Reconfigurable Terahertz Bandpass Filter Based on Double-Layered Subwavelength Metallic Rods
Abstract
Tunable bandpass terahertz filters are demanded in various key applications such as hyperspectral imagers, miniaturized spectrometers, and high-speed wireless communication systems. Here, a mechanically reconfigurable double-layered subwavelength metallic structure is presented for frequency-agile terahertz transmission bandpass filtering. The theoretically demonstrated polarization-insensitive filter shows remarkable performance metrics. By varying the vertical interlayer spacing of the metallic layers from 20 um to 4 um, the operation frequency tunes from 0.81 THz to 1.32 THz, and the full width at half maximum bandwidth changes from 209 GHz to 135 GHz, with maximum transmission efficiency greater than 98% and quality factor ranging between 3.88 and 9.77. A larger variation range of the vertical interlayer spacing leads to an enhanced frequency tuning range of the filter. Furthermore, simultaneous vertical and lateral interlayer displacements can provide polarization-dependent behavior for the filter. The underlying physical mechanism governing the filter's frequency response and tuning capability is analyzed by examining the electromagnetic field distributions within the double-layered subwavelength metallic structure and its Fabry-Perot-like behavior. The presented scheme holds significant promise for many terahertz applications due to its large tuning range, easy tuning mechanism, simple structure, and compatibility with fabrication materials and processes.
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