High-efficiency watt-level 1014 nm single-frequency laser based on short Yb-doped phosphate fiber amplifiers

Changsheng Yang; Shanhui Xu; Qi Yang; Wei Lin; Shupei Mo; Can Li; Zhouming Feng; Dongdan Chen; Zhongmin Yang; Zhonghong Jiang

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High-efficiency watt-level 1014 nm single-frequency laser based on short Yb-doped phosphate fiber amplifiers

机译：基于掺Yb的短磷酸盐光纤放大器的高效瓦特级1014 nm单频激光器

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摘要

High-efficiency single-frequency compact master-oscillator power amplifiers (MOPAs) based on core-pumped highly Yb-doped phosphate fibers (YPFs), several centimeters long, are investigated theoretically and experimentally. By using numerical modeling and testing different YPF lengths to optimize the amplifier configuration, a stable output of more than 1.06 W, at 1014 nm, was measured experimentally from a MOPA laser, with a 4.0 cm long YPF. An optical-to-optical conversion efficiency of 81.4%, a typical net gain of more than 20.5 dB, and an output power per unit length of up to 265 mW/cm were obtained with this laser system. The measured optical signal-to-noise ratio of the MOPA laser is higher than 62 dB and the estimated laser linewidth is less than 20 kHz, without obvious broadening or degradation after amplification. There is excellent agreement between the results of the simulations and the experiments.

机译：在理论上和实验上研究了基于芯泵浦，长Yb掺杂的磷酸盐纤维（YPF）的高效单频紧凑型主振荡器功率放大器（MOPA）。通过使用数值模型和测试不同的YPF长度来优化放大器配置，在MOPA激光器上使用YPF长度为4.0 cm的实验测量了在1014 nm处超过1.06 W的稳定输出。使用该激光系统可获得81.4％的光-光转换效率，超过20.5 dB的典型净增益以及高达265 mW / cm的每单位长度输出功率。测得的MOPA激光的光信噪比高于62 dB，估计的激光线宽小于20 kHz，放大后没有明显的展宽或劣化。模拟结果与实验之间有着极好的一致性。

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来源
《_Applied Physics Express》 |2014年第6期|062702.1-062702.4|共4页
作者
Changsheng Yang; Shanhui Xu; Qi Yang; Wei Lin; Shupei Mo; Can Li; Zhouming Feng; Dongdan Chen; Zhongmin Yang; Zhonghong Jiang;
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State Key Laboratory of Luminescent Materials and Devices and Institute of Optical Communication Materials,South China University of Technology, Guangzhou 510640, China;

State Key Laboratory of Luminescent Materials and Devices and Institute of Optical Communication Materials,South China University of Technology, Guangzhou 510640, China,Special Glass Fiber and Device Engineering Technology Research and Development Center of Guangdong Province,Guangzhou 510640, China;

State Key Laboratory of Luminescent Materials and Devices and Institute of Optical Communication Materials,South China University of Technology, Guangzhou 510640, China;

State Key Laboratory of Luminescent Materials and Devices and Institute of Optical Communication Materials,South China University of Technology, Guangzhou 510640, China;

State Key Laboratory of Luminescent Materials and Devices and Institute of Optical Communication Materials,South China University of Technology, Guangzhou 510640, China;

State Key Laboratory of Luminescent Materials and Devices and Institute of Optical Communication Materials,South China University of Technology, Guangzhou 510640, China;

State Key Laboratory of Luminescent Materials and Devices and Institute of Optical Communication Materials,South China University of Technology, Guangzhou 510640, China,Special Glass Fiber and Device Engineering Technology Research and Development Center of Guangdong Province,Guangzhou 510640, China;

State Key Laboratory of Luminescent Materials and Devices and Institute of Optical Communication Materials,South China University of Technology, Guangzhou 510640, China,Special Glass Fiber and Device Engineering Technology Research and Development Center of Guangdong Province,Guangzhou 510640, China;

State Key Laboratory of Luminescent Materials and Devices and Institute of Optical Communication Materials,South China University of Technology, Guangzhou 510640, China,Special Glass Fiber and Device Engineering Technology Research and Development Center of Guangdong Province,Guangzhou 510640, China;

State Key Laboratory of Luminescent Materials and Devices and Institute of Optical Communication Materials,South China University of Technology, Guangzhou 510640, China,Special Glass Fiber and Device Engineering Technology Research and Development Center of Guangdong Province,Guangzhou 510640, China;

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专利

1. 980-nm all-fiber mode-locked Yb-doped phosphate fiber oscillator based on semiconductor saturable absorber mirror and its amplifier [J] . Ping-Xue Li, Yi-Fei Yao, Jun-Jie Chi, 中国物理：英文版 . 2016,第008期

机译：基于半导体饱和吸收镜及其放大器的980nm全光纤锁模掺Yb磷酸盐光纤振荡器
2. Ultra Compact Kilohertz-Linewidth High-Power Single-Frequency Laser Based on Er~(3+)/Yb~(3+)-Codoped Phosphate Fiber Amplifier [J] . Changsheng Yang, Shanhui Xu, Can Li, _Applied Physics Express . 2013,第2期

机译：基于Er〜（3 +）/ Yb〜（3 +）-掺杂磷酸盐光纤放大器的超紧凑型千赫线宽大功率单频激光器
3. Single-frequency 1060 nm semiconductor-optical-amplifier-based fiber laser with 40 nm tuning range [J] . Ming Tang, Xiaolong Tian, Xiaona Lu, Optics Letters . 2009,第14期

机译：基于单频1060 nm半导体光放大器的光纤激光器，调谐范围为40 nm
4. A tunable and stabilized single-frequency fiber ring laser based on hybrid amplifier and shorter length EDF with unpumped status [C] . Chien-Hung Yeh, Kuo-Pao Fan, Sien Chi Conference on ICO . 2006

机译：基于混合动力放大器的可调谐和稳定的单频光纤环激光，并且具有较短的EDF，具有未捕获状态
5. Ultrafast Lasers and Amplifiers Based on Yb-Doped Gain Materials [D] . Manchee, C. P. Kyle. 2019

机译：超快激光器和放大器基于YB掺杂增益材料
6. Injection-Locked Single Frequency Multi-core Yb-doped Phosphate Fiber Laser [O] . V. Demir, M. Akbulut, D. T. Nguyen, -1

机译：注入锁定单频多芯掺b磷酸盐光纤激光器
7. Yb^3+-doped double-clad phosphate fiber for 976 nm single-frequency laser amplifiers [O] . Wu Jingwei, Zhu Xiushan, Temyanko Valery, 2017

机译：掺Yb ^ 3 +的双包层磷酸盐光纤，用于976 nm单频激光放大器

High-efficiency watt-level 1014 nm single-frequency laser based on short Yb-doped phosphate fiber amplifiers

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