Fiber amplifiers and tunable fiber lasers working in near (NIR, 1.0~1.7μm) and middle infrared (MIR, 2~5μm) regions are being extensively investigated owing to their various potential applications in optical telecommunication, environmental monitoring, remote sensing and so forth.[1,2] PbS quantum dot (QD) doped glass fiber with tunable broadband NIR emission and rare-earth-ion (such as Er3+) doped glass ceramic fiber with enhanced MIR emission are well suitable for the above-described applications. Importantly, novel “melt-in-tube” method is developed to solve the key bottleneck problem of uncontrollable rapid growth of QDs or nanocrystals existing in traditional fiber-drawing technique.[3,4] Furthermore, thermal and optical properties between fiber core and cladding glass are well matched, which ensure that the structure of the precursor fiber is well preserved during the fiber-drawing process. The excellent spectroscopic characteristics and well-preserved structure suggest that the obtained glass fiber may be a promising material for fiber amplifiers and tunable fiber lasers.
References
[1] Shiliang Kang, Zaijin Fang, Xiongjian Huang, Zhi Chen, Dandan Yang, Xiudi Xiao, Jianrong Qiu, Guoping Dong, Journal of Materials Chemistry C 5(2017) 4549-4556.
[2] Haipeng Wang, Guobo Wu, Jianrong Qiu, Guoping Dong, Optics Express 23(2015) 16723-16729.
[3] Xiongjian Huang, Zaijin Fang, Zixing Peng, Zhijun Ma, Haitao Guo, Jianrong Qiu, Guoping Dong, Optics Express 25(2017) 19691-19700.
[4] Xiongjian Huang, Zaijin Fang, Shiliang Kang, Wencai Peng, Guoping Dong, Bo Zhou, Zhijun Ma, Shifeng Zhou, Jianrong Qiu, Journal of Materials Chemistry C 5(2017) 7927-7934.
| Subject : | : | Oral |
| Topics | : | FIBERS 2 |
| Keywords | : | Glass Ceramic Fibers ; Nanocrystal ; Near/Mid ; Infrared Emission |
| PDF version | : |  PDF version |
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