Bismuth activated alumosilicate optical fibers fabricated by surface-plasma chemical vapor deposition technology

Igor A. Bufetov; Konstantin M. Golant; Sergey V. Firstov; Artem V. Kholodkov; Alexey V. Shubin; Evgeny M. Dianov

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Bismuth activated alumosilicate optical fibers fabricated by surface-plasma chemical vapor deposition technology

机译：表面等离子体化学气相沉积技术制备的铋活化铝硅酸盐光纤

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Plasma chemical technology is experimentally applied to the fabrication of a Bi-activated alumosilicate-core pure-silica-cladding fiber preform. To the best of our knowledge, this is the first time this technology has been applied in this way. We measure gain efficiency at pumping by a 1058 nm wavelength Yb fiber laser in a piece of a newly obtained fiber 20 m in length within 100-1200 nm wavelengths band. The gain efficiency reaches as high as 0.2 dB/mW. Bi-activated alumosilicate-core pure-silica-cladding fiber that is not more than 12 m in length serves a basis for a 1 W output power fiber laser emitting at the wavelength of 1160 nm with 8percent slope efficiency. We also measure the photoluminescence spectrum and kinetics of Bi centers responsible for laser emission under the excitation of 193 nm wavelength ArF laser pulses.

机译：等离子体化学技术已被实验性地应用于Bi活化的铝硅酸盐芯纯硅包层光纤预制棒的制造。据我们所知，这是这种技术的首次应用。我们测量了波长为1058 nm的Yb光纤激光器在一条新获得的长度为20 m的光纤中在100-1200 nm波段内泵浦时的增益效率。增益效率高达0.2 dB / mW。长度不超过12 m的双活化铝硅酸盐芯纯硅包层光纤是1 W输出功率光纤激光器的基础，该激光器在1160 nm波长处发射，斜率效率为8％。我们还测量了在193 nm波长ArF激光脉冲的激发下负责激光发射的Bi中心的光致发光光谱和动力学。

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《Applied optics》 |2008年第27期|共5页
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Igor A. Bufetov; Konstantin M. Golant; Sergey V. Firstov; Artem V. Kholodkov; Alexey V. Shubin; Evgeny M. Dianov;
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1. Bismuth activated alumosilicate optical fibers fabricated by surface-plasma chemical vapor deposition technology [J] . Igor A. Bufetov, Konstantin M. Golant, Sergey V. Firstov, Applied optics . 2008,第27期

机译：表面等离子体化学气相沉积技术制备的铋活化铝硅酸盐光纤
2. Optical properties of Yb~(3+)/Ho~(3+) co-doped air cladding silica-based fiber fabricated with plasma non-chemical vapor deposition method [J] . Changming Xia, Guiyao Zhou, Jiantao Liu, Applied Physics . 2015,第2期

机译：等离子体非化学气相沉积法制备的Yb〜（3 +）/ Ho〜（3+）共掺杂空气包覆二氧化硅基光纤的光学性能
3. Optical and laser properties of Tm3+-doped air-cladding fiber fabricated by plasma non-chemical vapor deposition [J] . Xia Changming, Zhou Guiyao, Liu Jiantao, Applied physics . 2015,第1期

机译：通过等离子体非化学气相沉积制备的掺Tm3 +的空气包覆光纤的光学和激光特性
4. Silica-Based Films and Multilayer Stacks for Lightwave Circuits Fabricated by Surface-Plasma Chemical Vapor Deposition [C] . K. M. Golant Korea-Japan Microwave Conference . 2008

机译：基于二氧化硅的薄膜和多层叠层，用于由表面等离子体化学气相沉积制造的光波电路
5. The optical deposition system for fabricating semiconductor cylinder fibers. [D] . Nivartvong, Nitipun. 2002

机译：用于制造半导体圆柱纤维的光学沉积系统。
6. Chemical Vapor Deposition of Organic-Inorganic Bismuth-Based Perovskite Films for Solar Cell Application [O] . S. Sanders, D. Stümmler, P. Pfeiffer, -1

机译：用于太阳能电池的有机-无机铋基钙钛矿薄膜的化学气相沉积
7. Optical properties of boron carbide (B\u3csub\u3e5\u3c/sub\u3eC) thin films fabricated by plasma-enhanced chemical-vapor deposition [O] . Ahmad, Ahmad A., Ianno, N.J., Snyder, P.G., 1996

机译：等离子体增强化学气相沉积制备碳化硼（B \ u3csub \ u3e5 / sub3）薄膜的光学特性
8. Preparation of Low-Loss Optical Fiber with Microwave Plasma Activated Chemical Vapor Deposition Process. [R] . Deng, D., Luo, H. 1983

机译：微波等离子体活化化学气相沉积法制备低损耗光纤。

Bismuth activated alumosilicate optical fibers fabricated by surface-plasma chemical vapor deposition technology

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