Molten core fabrication of bismuth germanium oxide Bi4Ge3O12 crystalline core fibers

Faugas, Benoît; Hawkins, Thomas; Kucera, Courtney; Bohnert, K.; Ballato, John

doi:10.1111/jace.15696

Cited by 9 publications

(2 citation statements)

References 35 publications

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“…Bismuth–germanate (BGO) is particularly attractive owing to its significance as the material candidate in high-energy physics, radiochemistry, nuclear physics, medicine imaging, and high-energy physics. − As a typical example, it accounted for 50% of the 256 million market for nuclear medical imaging. , The commercial BGO material is usually in the form of single crystal and has demonstrated its outstanding properties such as high density, nonhydroscopic, and super ray absorption ability. − ,, Although there is substantial progress in the crystal growth technique, it has been difficult to achieve a tiny array structure which is critical for construction of a panel detector . The attempts to overcome this limitation include employing the advanced crystal fiber drawing method or machining the bulk crystal into crystal fiber via a top-down approach.…”

Section: Introductionmentioning

confidence: 99%

Multiphase Transition toward Colorless Bismuth–Germanate Scintillating Glass and Fiber for Radiation Detection

Shi

Tang

et al. 2020

ACS Appl. Mater. Interfaces

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The applications of scintillating fiber in high-resolution medical imaging, remote radiation monitoring, and microbeam radiation therapy have raised a growing demand of bismuth–germanate (BGO) glass fiber. However, the task of construction of colorless BGO glass fiber has been met with limited success. Here, we present a renewable process that can help to achieve BGO scintillating fiber, based on glass relaxation and crystallization mediated dissolution of unexpected Bi center. The experimental results indicate that the strategy can improve the optical transmittance up to more than 73.17% at 483 nm, which is ∼6.28 times higher than that of the conventional material. Importantly, the obtained nanostructured BGO exhibits bright visible luminescence under excitation with X-ray. Furthermore, it can host various types of rare-earth dopants, and the radiation-induced luminescence can be tuned in a wide waveband region from visible to infrared waveband. In addition, colorless BGO fiber with bright emission is also successfully constructed, and the radiation probing test demonstrates the achievement of ∼19.48 times improvement in the detection sensitivity. Our results highlight the approach based on the dynamic glass relaxation may provide new opportunities for construction of scintillating glass fiber and compact radiation fiber detector.

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Section: Introductionmentioning

confidence: 99%

Multiphase Transition toward Colorless Bismuth–Germanate Scintillating Glass and Fiber for Radiation Detection

Shi

Tang

et al. 2020

ACS Appl. Mater. Interfaces

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“…On the other hand, reactive molten-core fabrication has proven to be an effective method to fabricate fibers with core materials which cannot be drawn into fibers on their own [22][23][24]. With the housing material reacting with the core material via various mechanisms, such as reactive chemistry, dissolution, and diffusion, fibers with various core materials, such as semiconductors, special glass, and crystalline oxides, have been reported [22][23][24][25][26][27][28][29][30]. Therefore, in this paper we report on the fabrication of glass-clad BTS glass-ceramic fibers using the powder-in-tube reactive molten-core approach with a successive isothermal heat treatment.…”

Section: Introductionmentioning

confidence: 99%

Powder-in-Tube Reactive Molten-Core Fabrication of Glass-Clad BaO-TiO2-SiO2 Glass–Ceramic Fibers

et al. 2020

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In this paper we report the fabrication of glass-clad BaO-TiO2-SiO2 (BTS) glass–ceramic fibers by powder-in-tube reactive molten-core drawing and successive isothermal heat treatment. Upon drawing, the inserted raw powder materials in the fused silica tubing melt and react with the fused silica tubing (housing tubing) via dissolution and diffusion interactions. During the drawing process, the fused silica tubing not only serves as a reactive crucible, but also as a fiber cladding layer. The formation of the BTS glass–ceramic structure in the core was verified by micro-Raman spectroscopy after the successive isothermal heat treatment. Second-harmonic generation and blue-white photoluminescence were observed in the fiber using 1064 nm and 266 nm picosecond laser irradiation, respectively. Therefore, the BTS glass–ceramic fiber is a promising candidate for all fiber based second-order nonlinear and photoluminescence applications. Moreover, the powder-in-tube reactive molten core method offers a more efficient and intrinsic contamination-free approach to fabricate glass–ceramic fibers.

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(INVITED) Hybrid glass optical fibers-novel fiber materials for optoelectronic application

Kang

Dong

Qiu

et al. 2020

Optical Materials: X

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Molten core fabrication of bismuth germanium oxide Bi₄Ge₃O₁₂ crystalline core fibers

Cited by 9 publications

References 35 publications

Multiphase Transition toward Colorless Bismuth–Germanate Scintillating Glass and Fiber for Radiation Detection

Multiphase Transition toward Colorless Bismuth–Germanate Scintillating Glass and Fiber for Radiation Detection

Powder-in-Tube Reactive Molten-Core Fabrication of Glass-Clad BaO-TiO2-SiO2 Glass–Ceramic Fibers

(INVITED) Hybrid glass optical fibers-novel fiber materials for optoelectronic application

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