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Singlemoded THz guidance in bendable TOPAS suspended-core fiber directly drawn from a 3D printer

Wanvisa Talataisong, Jon Gorecki, Rand Ismaeel, Martynas Beresna, Daniel Schwendemann, Vasilis Apostolopoulos, Gilberto Brambilla

2020Scientific Reports34 citationsDOIOpen Access PDF

Abstract

Terahertz (THz) technology has witnessed a significant growth in a wide range of applications, including spectroscopy, bio-medical sensing, astronomical and space detection, THz tomography, and non-invasive imaging. Current THz microstructured fibers show a complex fabrication process and their flexibility is severely restricted by the relatively large cross-sections, which turn them into rigid rods. In this paper, we demonstrate a simple and novel method to fabricate low-cost THz microstructured fibers. A cyclic olefin copolymer (TOPAS) suspended-core fiber guiding in the THz is extruded from a structured 3D printer nozzle and directly drawn in a single step process. Spectrograms of broadband THz pulses propagated through different lengths of fiber clearly indicate guidance in the fiber core. Cladding mode stripping allow for the identification of the single mode in the spectrograms and the determination of the average propagation loss (~ 0.11 dB/mm) in the 0.5-1 THz frequency range. This work points towards single step manufacturing of microstructured fibers using a wide variety of materials and geometries using a 3D printer platform.

Topics & Concepts

Terahertz radiationMaterials scienceCladding (metalworking)OpticsCore (optical fiber)FabricationFiberOptoelectronicsSingle-mode optical fiberOptical fiberPhysicsComposite materialAlternative medicineMedicinePathologyTerahertz technology and applicationsSuperconducting and THz Device TechnologyPhotonic and Optical Devices
Singlemoded THz guidance in bendable TOPAS suspended-core fiber directly drawn from a 3D printer | Litcius