Infrared glass-based negative-curvature anti-resonant fibers fabricated through extrusion

Gattass, Rafael R.; Rhonehouse, Daniel L.; Gibson, Dan; McClain, Collin; Thapa, Rajesh; Nguyen, Vinh; Bayya, Shyam; Weiblen, R. Joseph; Menyuk, Curtis R.; Shaw, L. Brandon; Sanghera, Jasbinder S.

doi:10.1364/oe.24.025697

Cited by 69 publications

(43 citation statements)

References 21 publications

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“…This type of hollow-core fiber (HCF), referred to as hollow-core negative curvature fiber (NCF) in this paper (or more broadly named hollow-core anti-resonant fiber (ARF)) shows similar level of transmission loss and single modeness with the maturely developed hollow-core photonic-bandgap fiber (PBGF) and outperforms the PBGF in terms of broadband light guidance and high laser damage threshold. It has found plenty of interdisciplinary applications in areas ranging from ultra-intense pulse delivery [8,9], single-cycle pulse generation [10,11], low latency optical communication [5], UV light sources [12,13], mid-IR gas lasers [14] to biochemical sensing [15,16], quantum optics [17] and mid-IR to Terahertz waveguides [18,19]. In some of these applications, NCF has the potential to revolutionize the research field by realizing unprecedented performances, e.g.…”

Section: Introductionmentioning

confidence: 99%

Confinement loss in hollow-core negative curvature fiber: A multi-layered model

Wang¹,

Ding²

2017

Opt. Express

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Abstract:Simple structures are always a pursuit but sometimes not easily attainable. It took researchers nearly two decades for conceiving the structure of single-ring hollow-core negative curvature fiber (NCF). Recently NCF eventually approaches to the centre of intense study in fiber optics. The reason behind this slow-pace development is, undoubtfully, its inexplicit guidance mechanism. This paper aims at gaining a clear physical insight into the optical guidance mechanism in NCF. To clarify the origins of light confinement, we boldly disassemble the NCF structure into several layers and develop a multi-layered model. Four physical origins, namely single-path Fresnel transmission through cascaded interfaces, near-grazing incidence, multi-path interference caused by Fresnel reflection, and glass wall shape are revealed and their individual contributions are quantified for the first time. Such an elegant model could not only elucidate the optical guidance in existing types of hollow-core fibers but also assist in design of novel structure for new functions.

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Section: Introductionmentioning

confidence: 99%

Confinement loss in hollow-core negative curvature fiber: A multi-layered model

Wang¹,

Ding²

2017

Opt. Express

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“…Figure 4 shows such a dependence for silica glass without taking into account the absorption of silica glass (line 1) and taking into account the absorption in the silica glass, provided that the wavelength corresponds to the center of the "zero" (line 2) and "second" (line 3) transmission band. The comparison of these lines shows that material losses can be neglected at short wavelengths only, but at wavelengths above ~4.7 μm they increase the total optical losses to the values above 1 dB/m (as was noted in [13].) Figure 4 also shows the analogous dependence for RF made of chalcogenide glass (line 5).…”

Section: Rf Design Optimization Based On Analytical Modelsmentioning

confidence: 60%

The Design Optimization and Experimental Investigation of the 4.4 μm Raman Laser Basedon Hydrogen-filled Revolver Silica Fiber

Kolyadin¹,

Astapovich²,

Gladyshev³

et al. 2018

KEn

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Annotation. Optical properties of hollow-core revolver fibers are numerically investigated depending on various parameters: the hollow-core diameter, the capillary wall thickness, the values of the minimum gap between the capillaries, the number of capillaries in the cladding and the type of glass (silica and chalcogenide). Preliminary, similar calculations are made for simple models of hollow-core fibers. Based on the obtained results, the optimal design of the revolver fiber for Raman laser frequency conversion (1.56 μm → 4.4 μm in 1 H 2 ) was determined. As a result, efficient ns-pulsed 4.42 µm Raman laser based on 1 H 2 -filled revolver silica fiber is realized. Quantum efficiency as high as 36 % is achieved and output average power as high as 250 mW is demonstrated.

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“…The first 6-rings of holes, hollow-core fiber, obtained in 2010 did not permitted any light propagation [13]. Later, A. Kosolapov et al [14], and R. Gattas et al [15] demonstrated light guidance beyond 10 μm through a Te-As-Se glass hollow-core fiber, and through an As-S hollow-core fiber respectively.…”

Section: Fiber Designs For Mid-infrared-guidingmentioning

confidence: 99%

Original designs of chalcogenide microstuctured optical fibers

Trolès

Brilland²,

Caillaud

et al. 2017

Advanced Device Materials

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The combination of the unique optical properties of chalcogenide glasses, in terms of infrared transmission and optical non-linearity, with the original guiding properties of microstructured optical fibers leads to a new category of fibers with promising applications in mid-infrared optics. The recent developments on chalcogenide microstructured optical fibers are exposed and discussed with regards to mid-IR guiding, infrared light transport and delivery, generation of new infrared sources, and infrared spectroscopy.

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Infrared glass-based negative-curvature anti-resonant fibers fabricated through extrusion

Cited by 69 publications

References 21 publications

Confinement loss in hollow-core negative curvature fiber: A multi-layered model

Confinement loss in hollow-core negative curvature fiber: A multi-layered model

The Design Optimization and Experimental Investigation of the 4.4 μm Raman Laser Basedon Hydrogen-filled Revolver Silica Fiber

Original designs of chalcogenide microstuctured optical fibers

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