Thomas Hawkins scite author profile

Described herein are initial experimental details and properties of a silicon core, silica glass-clad optical fiber fabricated using conventional optical fiber draw methods. Such semiconductor core fibers have potential to greatly influence the fields of nonlinear fiber optics, infrared and THz power delivery. More specifically, x-ray diffraction and Raman spectroscopy showed the core to be highly crystalline silicon. The measured propagation losses were 4.3 dB/m at 2.936 microm, which likely are caused by either microcracks in the core arising from the large thermal expansion mismatch with the cladding or to SiO(2) precipitates formed from oxygen dissolved in the silicon melt. Suggestions for enhancing the performance of these semiconductor core fibers are provided. Here we show that lengths of an optical fiber containing a highly crystalline semiconducting core can be produced using scalable fiber fabrication techniques.

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Sapphire-derived all-glass optical fibres

Dragic

et al. 2012

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Glass-clad single-crystal germanium optical fiber

Ballato¹,

Hawkins²,

Foy³

et al. 2009

Opt. Express

137

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Long lengths (250 meters) of a flexible 150 microm diameter glass-clad optical fiber containing a 15 microm diameter crystalline and phase-pure germanium core was fabricated using conventional optical fiber draw techniques. X-ray diffraction and spontaneous Raman scattering measurements showed the core to be very highly crystalline germanium with no observed secondary phases. Elemental analysis confirmed a very well-defined core-clad interface with a step-profile in composition and nominally 4 weight-percent oxygen having diffused into the germanium core from the glass cladding. For this proof-of-concept fiber, polycrystalline n-type germanium of unknown dopant concentration was used. The measured infrared transparency of the starting material was poor and, as a likely outcome, the attenuation of the resultant fiber was too high to be measured. However, the larger Raman cross-section, infrared and terahertz transparency of germanium over silicon should make these fibers of significant value for fiber-based mid- to long-wave infrared and terahertz waveguides and Raman-shifted infrared light sources once high-purity, high-resistivity germanium is employed.

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Transverse Anderson localization in a disordered glass optical fiber

Karbasi¹,

Hawkins²,

Ballato³

et al. 2012

Opt. Mater. Express

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CO₂ Laser‐Induced Directional Recrystallization to Produce Single Crystal Silicon‐Core Optical Fibers with Low Loss

Healy

Fokine

Franz

et al. 2016

Advanced Optical Materials

101

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Thomas Hawkins

Silicon optical Fiber

Sapphire-derived all-glass optical fibres

Glass-clad single-crystal germanium optical fiber

Transverse Anderson localization in a disordered glass optical fiber

CO₂ Laser‐Induced Directional Recrystallization to Produce Single Crystal Silicon‐Core Optical Fibers with Low Loss

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About

Thomas Hawkins

Silicon optical Fiber

Sapphire-derived all-glass optical fibres

Glass-clad single-crystal germanium optical fiber

Transverse Anderson localization in a disordered glass optical fiber

CO2 Laser‐Induced Directional Recrystallization to Produce Single Crystal Silicon‐Core Optical Fibers with Low Loss

Contact Info

Product

Resources

About

CO₂ Laser‐Induced Directional Recrystallization to Produce Single Crystal Silicon‐Core Optical Fibers with Low Loss