Fabrication of Yb-doped silica micro-structured optical fibers from UV-curable nano-composites and their application in temperature sensing
•Yb3+ doped silica glass and pure silica glass structure are fabricated based on UV-curable nano-composites.•Optical and material properties of the Yb3+ -doped silica glass are characterized and investigated.•There is virtually no difference between the 3D printed silica glass structure and commerci...
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| Published in: | Journal of non-crystalline solids Vol. 573; p. 121129 |
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01-12-2021
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| Abstract | •Yb3+ doped silica glass and pure silica glass structure are fabricated based on UV-curable nano-composites.•Optical and material properties of the Yb3+ -doped silica glass are characterized and investigated.•There is virtually no difference between the 3D printed silica glass structure and commercial fused silica glass.•Yb-doped silica micro structured optical fibers are fabricated, investigated and applied to high temperature sensing.
A novel scheme for fabricating Yb-doped silica micro structured optical fibers and their application in high-temperature optical fiber sensing are reported. The Yb-doped silica micro structured optical fiber preforms consisted of Yb-doped silica core rods (0.1 wt% for Yb2O3) and holey pure silica claddings fabricated by UV-curable tube molding technology and digital light processing 3D printing technology, respectively. The silica preforms were drawn using the rod-in-tube method to Yb-doped silica micro structured optical fibers without severe distortion. The doped micro structured fibers were applied to high-temperature sensing from 296.15 to 653.15 K. The proposed technology is expected to be effective for the fabrication of various types of rare-earth-ion-doped silica micro structured optical fibers that can be used in fiber sensors, lasers, and amplifiers. |
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| AbstractList | •Yb3+ doped silica glass and pure silica glass structure are fabricated based on UV-curable nano-composites.•Optical and material properties of the Yb3+ -doped silica glass are characterized and investigated.•There is virtually no difference between the 3D printed silica glass structure and commercial fused silica glass.•Yb-doped silica micro structured optical fibers are fabricated, investigated and applied to high temperature sensing.
A novel scheme for fabricating Yb-doped silica micro structured optical fibers and their application in high-temperature optical fiber sensing are reported. The Yb-doped silica micro structured optical fiber preforms consisted of Yb-doped silica core rods (0.1 wt% for Yb2O3) and holey pure silica claddings fabricated by UV-curable tube molding technology and digital light processing 3D printing technology, respectively. The silica preforms were drawn using the rod-in-tube method to Yb-doped silica micro structured optical fibers without severe distortion. The doped micro structured fibers were applied to high-temperature sensing from 296.15 to 653.15 K. The proposed technology is expected to be effective for the fabrication of various types of rare-earth-ion-doped silica micro structured optical fibers that can be used in fiber sensors, lasers, and amplifiers. |
| ArticleNumber | 121129 |
| Author | Zhang, Xin Zheng, Baoluo Yang, Jing Qi, Fuxin Wang, Jinhang Wang, Pu |
| Author_xml | – sequence: 1 givenname: Baoluo surname: Zheng fullname: Zheng, Baoluo organization: Key Laboratory of Trans-scale Laser Manufacturing Technology, Beijing University of Technology, Ministry of Education, Beijing 100124 China – sequence: 2 givenname: Jing surname: Yang fullname: Yang, Jing organization: Key Laboratory of Trans-scale Laser Manufacturing Technology, Beijing University of Technology, Ministry of Education, Beijing 100124 China – sequence: 3 givenname: Fuxin surname: Qi fullname: Qi, Fuxin organization: Key Laboratory of Trans-scale Laser Manufacturing Technology, Beijing University of Technology, Ministry of Education, Beijing 100124 China – sequence: 4 givenname: Jinhang surname: Wang fullname: Wang, Jinhang organization: Key Laboratory of Trans-scale Laser Manufacturing Technology, Beijing University of Technology, Ministry of Education, Beijing 100124 China – sequence: 5 givenname: Xin surname: Zhang fullname: Zhang, Xin organization: Key Laboratory of Trans-scale Laser Manufacturing Technology, Beijing University of Technology, Ministry of Education, Beijing 100124 China – sequence: 6 givenname: Pu surname: Wang fullname: Wang, Pu email: wangpuemail@bjut.edu.cn organization: Key Laboratory of Trans-scale Laser Manufacturing Technology, Beijing University of Technology, Ministry of Education, Beijing 100124 China |
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| Keywords | Micro-structured optical fibers Porous silica Temperature sensing 3D printing Curable nano composites Rare-earth doped |
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Photon. doi: 10.1117/1.AP.2.2.024001 contributor: fullname: Song – volume: 31 start-page: 175 year: 2004 ident: 10.1016/j.jnoncrysol.2021.121129_bib0021 article-title: Application of the Sol-Gel Method at the Fabrication of Microstructure Fibers publication-title: J. Sol-Gel Sci. Technol. doi: 10.1023/B:JSST.0000047982.14815.65 contributor: fullname: Mrazek |
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| SubjectTerms | 3D printing Curable nano composites Micro-structured optical fibers Porous silica Rare-earth doped Temperature sensing |
| Title | Fabrication of Yb-doped silica micro-structured optical fibers from UV-curable nano-composites and their application in temperature sensing |
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