Embodiments of the present invention relate generally to the design and precise fabrication of a hollow-core anti-resonant fiber, and more particularly to a hollow-core fiber made from an extruded soft glass preform that utilizes a single layer of robust reflecting optical arches for transmission of mid- to long-infrared light. The guidance mechanism and design of this fiber allow the low-loss transmission of wavelengths of light which falls within the high absorption spectrum of the confining material.
The hollow-core photonic band gap (HC-PBG) fiber is a special photonic crystal fiber design, which guides light in the air-core surrounded by a periodic 2-dimensional array of small holes in the cladding (see, for example, J. C. Knight, J. Broeng, T. A. Birks, and P. S. J. Russell, “Photonic band gap guidance in optical fibers,” Science 282(5393), 1476-1478 (1998)). In the HC-PBG fiber the light is substantially confined to the hollow core by virtue of the periodic photonic band gap structure of the cladding. However, the guided light in the core strongly overlaps with the glass contour microstructure, which limits the HC-PBG transmission range to the transparency of the glass material used because of the light absorption in the glass struts.
Hollow-core anti-resonant (HC-AR) fiber is an alternative approach to HC-PBG fiber to minimize the light overlap in the glass struts. The hollow core is surrounded by thin glass struts of equal thickness t and refractive index n designed such that multiple wide transmission wavelength bands are centered between the high-loss resonant wavelengths of the fiber at:
The anti-resonance in the thin glass struts at the interface of the hollow core and the cladding (core surround) efficiently reflects and confines the light in the hollow core. The HC-AR fiber can transmit longer wavelengths than otherwise possible in the glass itself because the light does not penetrate in the material.
HC-AR fiber with circular core surround, like the Kagome fiber (see, for example, F. Couny, F. Benabid, and P. S. Light, “Large-pitch kagome-structured hollow-core photonic crystal fiber,” Opt. Lett. 31(24), 3574-3576 (2006)), confines more of the light in the air core but has a relatively high transmission loss (>1 dB/m) caused by the scattering of undesired and thicker nodes at the intersection between struts. The improved Kagome fiber with negative curvature core surround pushes the nodes away from the air core and significantly reduces the transmission loss <0.1 dB/m (see, for example, Y. Y. Wang, N. V. Wheeler, F. Couny, P. J. Roberts, and F. Benabid, “Low loss broadband transmission in hypocycloid-core Kagome hollow-core photonic crystal fiber,” Opt. Lett. 36(5), 669-671 (2011)). Studies have demonstrated that most of the light confinement in the Kagome lattice fibers occurs due to anti-resonance in the core surrounding ring with little contribution due to the second ring: the remaining part of the periodic layers of holes is not effective at creating coherent reflections and has almost no light-guiding role.
This has resulted in the development of simplified HC-AR fibers with just one ring of capillary tubes surrounding its core. Recent improvements include the more efficient HC-AR fiber with a single row of non-touching tubes (see, for example, A. N. Kolyadin, A. F. Kosolapov, A. D. Pryamikov, A. S. Biriukov, V. G. Plotnichenko, and E. M. Dianov, “Light transmission in negative curvature hollow core fiber in extremely high material loss region,” Opt. Express 21(8), 9514-9519 (2013)). The non-touching tube lattice structure eliminates the undesired scattering loss at the touching nodes and can achieve a low fiber transmission loss of <1 dB/m, even at long wavelengths up to 4 microns where the silica glass material absorption is very high, such as >880 dB/m. Additionally, simulations have shown that the higher order modes of the HC-AR fiber are more attenuated than the fundamental mode, so the fiber is purely single mode after only a few meters. However, silica cannot be used for HC-AR fiber at wavelengths >4.3 microns because the small portion of the guided light that interacts with the silica core-surround is highly absorbed and does not propagate far. Further, the manufacture of such single-ring non-touching tube fiber with the conventional stack-and-draw technique is very challenging. The precise stacking of the non-touching tubes in the preform is difficult to achieve and maintain up to the fiber draw. Variations in tube thickness and spacing will inevitably change the fiber transmission performances.
The use of infrared glasses for the fabrication of simplified HC-AR fiber is attractive for extending the transmission to longer wavelengths such as >4.3 microns. However, infrared glasses are soft with low melting temperature, and the manufacturing process of HC-AR fiber with soft glass is even more challenging. The stack-and-draw technique was unsuccessful in the fabrication of HC-AR fiber with a single row of touching chalcogenide glass tubes (see, for example, V. S. Shiryaev, “Chalcogenide glass hollow-core microstructured optical fibers,” Frontier in Materials 2(24), 1-10 (2015)). Furthermore, it would be extremely unlikely to successfully use the stack-and-draw technique with infrared soft glasses to manufacture the HC-AR fiber with non-touching tubes while controlling precisely the thickness, shape, and spacing between tubes.
Extrusion is an alternative to the stack-and-draw technique for making HC-AR fiber with soft glass. The first extruded HC-AR fiber had a hexagonal core with a single ring of 6 cladding holes (see G. Tsiminis, K. J. Rowland, E. P. Schartner, N. A. Spooner, T. M. Monro, and H. Ebendorff-Heidepriem, “Single-ring hollow core optical fibers made by glass billet extrusion for Raman sensing,” Opt. Express 24(6), 5911-5917, (2016)). This first demonstration was made with lead-silicate glass (F2, Schott) and produced HC-AR fiber with very a high transmission loss of >20 dB/m in the visible wavelengths.
Infrared soft glass, chalcogenide, has recently been extruded to produce HC-AR “tube-like” fibers (see R. R. Gattass, D. Rhonehouse, D. Gibson, C. C. McClain, R. Thapa, V. Nguyen, S. S. Bayya, R. J. Weiblen, C. R. Menyuk, L. B. Shaw, J. S. Sanghera, “Infrared glass-based negative-curvature anti-resonant fibers fabricated through extrusion,” Opt. Express 24(22), 25697-25703, (2016)). The die was fabricated to extrude a preform with a single row of eight non-touching tubes. The extruded preform had relatively thick inner tube wall thickness, approximately 350 microns, and had to be pressurized to draw the HC-AR fiber with 7 microns inner tube wall thickness. The produced HC-AR fiber showed some transmission in the long-infrared window around 10 microns, but it had significant fabrication imperfections (variations in inner tubes diameter (±8%), thickness (±7%), and spacing (±34%)) that resulted in “blurring” of the transmission band and fairly high transmission loss >2.1 dB/m. The non-touching tubes are susceptible to lateral movement during fiber fabrication, especially when pressurization is used. The fabrication of HC-AR fiber with non-touching tubes appears to be difficult to use with soft glass while controlling precisely the thickness, shape, and spacing between tubes.
The above-mentioned fiber designs offer some viable solutions and some drawbacks for the fabrication of HC-AR fibers. However, none of them can efficiently use infrared soft glasses to produce the desired HC-AR fiber for mid- to long-infrared light with the tight geometry tolerances (<5%) required to achieve a low transmission loss of <1 dB/m. Low melting temperature infrared soft glasses enable the opportunity to use extrusion techniques to precisely produce preforms with unique shapes and features. Consequently, there is a need for new HC-AR fiber designs and fabrication techniques that would enable the tight geometry tolerances and the low transmission loss in the mid- to long-infrared.
Embodiments of the present invention concern the use of infrared soft glass to produce an improved hollow-core fiber, using a single layer of anti-resonant optical arches to offer low-loss transmission of <1 dB/m in the mid- to long-infrared range (1-15 microns). The curved arches have a thickness corresponding to the anti-resonance wavelength and are precisely spaced between one another to minimize the fiber transmission loss and to have the fiber effectively in single mode operation. Each arch is solidly attached at two locations on the outer solid region to prevent any lateral displacement and to preserve the arches' shape and uniformity during the fabrication process.
Embodiments also use extrusion to provide the preform with the hollow-core and anti-resonant arches. Three-dimensional (3D) printing (additive manufacturing) with metals is used to produce the extrusion die with an added high-precision machining at the die exit surface to produce high dimension tolerances and reduce the roughness of the inside walls of the die, thereby extruding the hollow-core preform with a smooth surface and very tight dimension tolerances (<5%).
Embodiments also pull the preform into the hollow-core fiber with anti-resonant arches to transmit light that is highly attenuated in the glass material (absorption of about >30 dB/m), and to have a fiber guidance loss of about <1 dB/m in the mid- to long-infrared (1-15 microns).
The present invention will now further be described with reference to the appended drawings, which illustrate various non-limitative embodiments of the present invention.
The accompanying drawings illustrate certain aspects of embodiments of the present invention, and should not be used to limit the invention. Together with the written description the drawings serve to explain certain principles of the invention.
Reference will now be made in detail to various exemplary embodiments of the invention. It is to be understood that the following discussion of exemplary embodiments is not intended as a limitation on the invention. Rather, the following discussion is provided to give the reader a more detailed understanding of certain aspects and features of the invention.
Generally, a hollow-core fiber is designed and made from an extruded soft glass preform that utilizes a single layer of robust reflecting optical arches for transmission of mid- to long-infrared light.
More precisely,
Soft glass has a low melting temperature, <800° C., and can be extruded into rods or tubes of various shapes. Soft glasses for preferred embodiments include infrared glasses such as chalcogenide, fluoride, and tellurite, for example. Typically, the soft glass is inserted in a sleeve inside an oven and pushed with a piston through a die designed for the extrusion process. The extrusion die can be made of metals like stainless steel, titanium alloy, aluminum alloy, or Inconel, for example.
The extruded hollow-core preform with anti-resonant arches is pulled in a fiber using traditional fiber draw techniques. The hollow-core preform is attached to a preform feed and connected to pressurization system where the hollow core and the anti-resonant arches can be independently pressurized. The preform is lowered in the oven at constant feed speed. The heated preform tip forms a bead that drops down the fiber draw tower carrying the fiber. The fiber is pulled and spooled at a draw speed of typically between 2 to 20 m/min. Typical pressures inside the hollow-core preform with anti-resonant arches are controlled within a range between 0 to 50 mbar to precisely adjust the fiber geometries with the desired hollow core diameter and arch dimensions; basically, a higher inner pressure increases the arches' size and reduces the arches' wall thickness.
The hollow-core preform with anti-resonant arches was extruded with the extrusion die showed in
Referring to
Example 2 relates to a design of the hollow-core fiber with 8 anti-resonant arches for the transmission of CO2 laser light at 10.6 microns. The fiber parameters used for the simulations are: As2S3 glass, a hollow core diameter of 0.185 mm, an anti-resonant arch wall thickness of 3.7 microns, and a gap between the arches of 21.5 microns.
The present invention has been described with reference to particular embodiments having various features. In light of the disclosure provided above, it will be apparent to those skilled in the art that various modifications and variations can be made in the practice of the present invention without departing from the scope or spirit of the invention. One skilled in the art will recognize that the disclosed features may be used singularly, in any combination, or omitted based on the requirements and specifications of a given application or design. When an embodiment refers to “comprising” certain features, it is to be understood that the embodiments can alternatively “consist of” or “consist essentially of” any one or more of the features. Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention.
It is noted in particular that where a range of values is provided in this specification, each value between the upper and lower limits of that range is also specifically disclosed. The upper and lower limits of these smaller ranges may independently be included or excluded in the range as well. The singular forms “a,” “an,” and “the” include plural referents unless the context clearly dictates otherwise. It is intended that the specification and examples be considered as exemplary in nature and that variations that do not depart from the essence of the invention fall within the scope of the invention. Further, all of the references cited in this disclosure are each individually incorporated by reference herein in their entireties and as such are intended to provide an efficient way of supplementing the enabling disclosure of this invention as well as provide background detailing the level of ordinary skill in the art.
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