Low-Loss Asymptotically Single-Mode THz Bragg Fiber Fabricated by Digital Light Processing Rapid Prototyping

Hong, Binbin; Swithenbank, Matthew; Greenall, Nicholas; Clarke, Roland; Chudpooti, Nonchanutt; Akkaraekthalin, Prayoot; Somjit, Nutapong; Cunningham, J. E.; Robertson, I.D.

doi:10.1109/tthz.2017.2778047

Cited by 25 publications

(36 citation statements)

References 46 publications

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“…Based on the cut-back method by comparing the amplitude of Ey at the start ( mm) and the end ( mm) of the zone III, the propagation loss of the fibre is estimated to be 4.78 dB/m, which is comparable to the experimental result of 3 dB/m in our previous experimental work [2].…”

Section: Addition Sincesupporting

confidence: 78%

“…However, it is challenging to fabricate extreme thin dielectric layer and long fibre using this technique, mainly limited by the printing resolution and the overall building space of the 3D printer. The complex refractive index of HTM140 used in this paper is based on the measurement results shown in [2].…”

Section: Design Of the Fibrementioning

confidence: 99%

“…In this paper, we investigate the mode transition and filtering phenomenon by using a 3D full-wave simulation of the EM wave propagation inside and along the length of a hollow all-polymer THz Bragg fibre, using directly measured material dielectric properties and with real geometric parameters [2]. The THz Bragg fibre discussed here can achieve asymptotical single-mode pattern propagation with large loss discrimination between the fundamental and other higher-order modes.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Investigation of electromagnetic mode transition and filtering of an asymptotically single-mode hollow THz Bragg fibre

Hong

Chudpooti

Akkaraekthalin

et al. 2018

J. Phys. D: Appl. Phys.

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The mechanism for electromagnetic (EM) mode transition and filtering in an asymptotically single-HE11-mode hollow THz Bragg fibre is investigated. We designed, fabricated, and measured Bragg fibres with an asymptotically single-mode pattern, achieving measured signal propagation loss of better than 3 dB/m at 0.265 THz and with an operating frequency range from 0.246 to 0.276 THz. Mode transition and filtering effects are both verified by 3D full-wave simulations using measured material properties, with geometrical parameters extracted from the fabricated Bragg fibre prototypes. By optimizing the coupling efficiency between the free-space Gaussian beam and the guided Bessel function mode, the optimum distance of mode transition from the Gaussian-beam excitation into the guided mode is calculated to be ~13.7 free-space wavelengths in our fibre, to ensure fast EM-field convergence to the desired asymptotically single-mode mode pattern in the Bragg fibre. After this mode transition region, the electric field amplitude ratio between the desired HE11 mode and the main competing HE12 mode is approximately 7 times, with the HE12 mode attenuation being more than 10 dB/m larger than the fundamental HE11 mode; the results indicate that our fibre is one of the best candidates for low-loss asymptotically single-mode terahertz signal interconnections.

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Section: Addition Sincesupporting

confidence: 78%

Section: Design Of the Fibrementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Investigation of electromagnetic mode transition and filtering of an asymptotically single-mode hollow THz Bragg fibre

Hong

Chudpooti

Akkaraekthalin

et al. 2018

J. Phys. D: Appl. Phys.

Self Cite

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show abstract

“…This fiber can propagate with low-loss propagation of 0.15 cm −1 (0.65 dB/cm) over frequencies higher than 0.35 THz. The cross-section of the single-mode and low-loss terahertz Bragg fiber presented in [71] can be seen in Figure 1h. The authors reached single mode propagation and Figure 1.…”

Section: Terahertz 3d Printed Waveguidesmentioning

confidence: 99%

“…The authors reached single mode propagation and Figure 1. (a) Porous polymer terahertz fiber design [38] (b) First all-dielectric 3D printed terahertz waveguide [64]; (c) 3D printed terahertz waveguide based on Kagome photonic crystal structure [65]; (d) Hollow-core with negative curvature [67]; (e) 3D-printed polymer antiresonant waveguide [68]; (f) 3D printed terahertz Bragg [69]; (g) Bragg waveguide with defect layers [70]; (h) Single-mode Bragg waveguide [71].…”

Section: Terahertz 3d Printed Waveguidesmentioning

confidence: 99%

3D Printed Hollow-Core Terahertz Fibers

Cruz

Cordeiro

Franco

2018

Fibers

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This paper reviews the subject of 3D printed hollow-core fibers for the propagation of terahertz (THz) waves. Several hollow and microstructured core fibers have been proposed in the literature as candidates for low-loss terahertz guidance. In this review, we focus on 3D printed hollow-core fibers with designs that cannot be easily created by conventional fiber fabrication techniques. We first review the fibers according to their guiding mechanism: photonic bandgap, antiresonant effect, and Bragg effect. We then present the modeling, fabrication, and characterization of a 3D printed Bragg and two antiresonant fibers, highlighting the advantages of using 3D printers as a path to make the fabrication of complex 3D fiber structures fast and cost-effective.

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Investigation on fiber‐based terahertz source

Zhang

Gong

2021

Micro & Optical Tech Letters

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A terahertz (THz) source based on hybrid Opt‐THz fiber, which is made of concentric central optical fiber and external Terahertz fiber, was proposed. With the enhanced second order nonlinearity in the central optical fiber, THz waves are distributed through difference frequency by high‐power optical pump laser. The external THz fiber will be designed with hollow fiber structure, and the THz waves are propagated and accumulated along the THz fiber. The simulation shows that the maximum THz power can reach ~4.8 mW after a 13.7 m optimal fiber length. The proposed THz source will be able to compete with existing THz sources in terms of power, compactness, frequency tunability and room‐temperature operation.

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Low-Loss Asymptotically Single-Mode THz Bragg Fiber Fabricated by Digital Light Processing Rapid Prototyping

Cited by 25 publications

References 46 publications

Investigation of electromagnetic mode transition and filtering of an asymptotically single-mode hollow THz Bragg fibre

Investigation of electromagnetic mode transition and filtering of an asymptotically single-mode hollow THz Bragg fibre

3D Printed Hollow-Core Terahertz Fibers

Investigation on fiber‐based terahertz source

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