Fiber-Drawn Metamaterial for THz Waveguiding and Imaging

Atakaramians, Shaghik; Stefani, Alessio; Li, Haisu; Habib, M. Samiul; Hayashi, Juliano G.; Tuniz, Alessandro; Tang, Xiaoli; Anthony, Jessienta; Lwin, Richard; Argyros, Alexander; Fleming, Simon; Kuhlmey, Boris T.

doi:10.1007/s10762-017-0383-0

Cited by 21 publications

(16 citation statements)

References 70 publications

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“…A variety of types of hollow waveguides have been studied for THz, which may be separated into metallic, dielectric and hybrid waveguides (including metamaterial waveguides). 3,4,5,6,7,8,9 Metallic hollow waveguides can have subwavelength cross-section and have relatively low loss. Those characteristics arguably make them the current best option for THz waveguides.…”

Section: Introductionmentioning

confidence: 99%

“…Metamaterial hollow waveguides offer the potential for control of the radiation, 5 can be subwavelength 6 and potentially low loss. 7 However, both complexity of fabrication and the relative lack of research in this field leaves doubts about their real potential. Dielectric THz hollow waveguides are the scaled version of their more successful optical counterpart and have been investigated in the form of Kagome structures, 10,11 simple capillaries, 12 antiresonant structures, 13 and several other variations.…”

Section: Introductionmentioning

confidence: 99%

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Terahertz orbital angular momentum modes with flexible twisted hollow core antiresonant fiber

2018

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THz radiation is more and more commonplace in research laboratories as well as in everyday life, with applications ranging from body scanners at airport security to short range wireless communications. In the optical domain, waveguides and other devices to manipulate radiation are well established. This is not yet the case in the THz regime because of the strong interaction of THz radiation with matter, leading to absorption, and the millimeter size of the wavelength and therefore of the required waveguides. We propose the use of a new material, polyurethane, for waveguides that allows high flexibility, overcoming the problem that large sizes otherwise result in rigid structures. With this material we realize antiresonant hollow-core waveguides and we use the flexibility of the material to mechanically twist the waveguide in a tunable and reversible manner, with twist periods as short as tens of wavelengths. Twisting the waveguide, we demonstrate the generation of modes carrying orbital angular momentum. We use THz time domain spectroscopy to measure and clearly visualize the vortex nature of the mode, which is difficult in the optical domain. The proposed waveguide is a new platform offering new perspectives for THz guidance and particularly mode manipulation. The demonstrated ability to generate modes with orbital angular momentum within a waveguide, in a controllable manner, will be beneficial to both fundamental, e.g. matter-radiation interaction, and applied, e.g. THz telecommunications, advances of THz research and technology. Moreover, this platform is not limited to the THz domain and could be scaled for other electromagnetic wavelengths.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Terahertz orbital angular momentum modes with flexible twisted hollow core antiresonant fiber

2018

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“…The holes in the preform are filled with a metal with a sufficiently low melting temperature that it is molten at the polymer drawing temperature. The structure is then drawn such that the polymer is still highly viscous and the liquid metal takes the form of the holes which reduce in diameter during drawing [11][12]. Figure 1 shows a schematic of a typical wire array metamaterial considered here.…”

Section: Tunable Metamaterials Based On Structural Deformationmentioning

confidence: 99%

“…Whilst fabrication of such structures of dissimilar materials on sub-wavelength scales is challenging, there have been numerous demonstrations [7], although few are scalable [8][9][10]. We have successfully fabricated metamaterials in volume by combining two scalable and well-established techniques: fiber drawing and the Taylor wire process [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Tunable metamaterials fabricated by fiber drawing

et al. 2017

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We demonstrate a practical scalable approach to the fabrication of tunable metamaterials. Designed for THz wavelengths, the metamaterial is comprised of polyurethane filled with an array of indium wires using the wellestablished fiber drawing technique. Modification of the dimensions of the metamaterial provides tunability: by compressing the metamaterial we demonstrated a 50% plasma frequency shift using THz time domain spectroscopy. Releasing the compression allowed the metamaterial to return to its original dimensions and plasma frequency, demonstrating dynamic reversible tunability.

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“…As fibers can accommodate more holes and thus, more electrodes, it is interesting to explore how far this thermal poling can be extended from just two anodes, and the extent to which an induced SON can be distributed through the volume of the glass. Such fibers are available due to recent advances in using fiber drawing for fabricating metamaterials with arrays of tens to hundreds of metal wires [10][11][12][13]. Poling these structures and inducing a SON may enable tunable metamaterials [14] with potential applications in sub-diffraction imaging and waveguide devices.…”

Section: Introductionmentioning

confidence: 99%

Thermal poling of multi-wire array optical fiber

Huang

Hayashi

et al. 2018

Opt. Express

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We demonstrate in this paper thermal poling of multi-wire array fibers, which extends poling of fibers with two anodes to ~50 and ~500 wire array anodes. The second harmonic microscopy observations show that second order nonlinearity (SON) layers are developed surrounding all the rings of wires in the ~50 anode array fiber with poling of 1.8kV, 250°C and 30min duration, and the outer rings of the ~500 anode array fiber at lower poling temperature. Our simulations based on a two-dimensional charge dynamics model confirm this can be explained by the self-adjustment mechanism, and show the SON layers are induced from the outer rings to the inner rings.

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Fiber-Drawn Metamaterial for THz Waveguiding and Imaging

Cited by 21 publications

References 70 publications

Terahertz orbital angular momentum modes with flexible twisted hollow core antiresonant fiber

Terahertz orbital angular momentum modes with flexible twisted hollow core antiresonant fiber

Tunable metamaterials fabricated by fiber drawing

Thermal poling of multi-wire array optical fiber

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