首页> 外文会议>High-Power Lasers and Applications III >The influence of KTP's thermal effects on the stabilization of a high- power diode-side-pumped all-solid-state QCW intracavity-frequency-doubled Nd:YAG laser and the compensating methods

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The influence of KTP's thermal effects on the stabilization of a high- power diode-side-pumped all-solid-state QCW intracavity-frequency-doubled Nd:YAG laser and the compensating methods

机译：KTP的热效应对高功率二极管侧泵全固态QCW腔内倍频Nd：YAG激光器的稳定性及其补偿方法的影响

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The stabilization and modes of a high-power intracavity frequency-doubled Nd:YAG laser are numerically analyzed, the great influence of frequency-doubler's thermal lensing on the stabilization and modes of this laser is demonstrated, and a compensating method is developed. A high-power QCW 532 nm green laser has been fabricated in the experiment, with a KTP crystal (θ = 90°, φ = 24.7°,6 x 6 x 9.2mm, cut for high-temperature(80℃) application) as frequency-doubler. With the KTP crystal warmed up to 48.8℃ and resonator parameters adjusted optimum according to the calculated thermal focal length of KTP crystal, a maximum 110W green laser is generated at 10.6kHz repetition rate, and it's pulse width is 142ns, instability 2%, and optical-to-optical efficiency 11%.

机译：数值分析了大功率腔内倍频Nd：YAG激光器的稳定性和模态，证明了倍频器的热透镜对这种激光器的稳定性和模态的巨大影响，并提出了一种补偿方法。实验中制备了一个大功率QCW 532 nm绿色激光器，其KTP晶体（θ= 90°，φ= 24.7°，6 x 6 x 9.2mm，已切成高温（80℃）应用）倍频器。将KTP晶体加热到48.8℃，并根据计算出的KTP晶体的热焦距将谐振器参数调整为最佳状态后，以10.6kHz的重复频率产生最大110W的绿色激光，脉冲宽度为142ns，不稳定2％，并且光学效率为11％。

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来源
《High-Power Lasers and Applications III》|2004年|P.299-306|共8页
会议地点 Beijing(CN)
作者
Zhou Rui; Xu Degang; Wen Wuqi; Ding Xin; Zhang Qiang; Wang Peng; Yao Jianquan;
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作者单位

Institute of Laser Opto-Electronics, College of Precision Instruments Opto-Electronics information, Tianjin University, Opto-electronic Information Key Lab of National Education Ministry, (300072) P.R.China;

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原文格式 PDF
正文语种 eng
中图分类激光技术、微波激射技术;
关键词
all-solid-state; green laser; QCW; KTP thermal effect; resonator optimize;

机译：全固态；绿色激光器； QCW； KTP热效应；谐振器优化;

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专利

1. Stabilization of a high-power diode-side-pumped intracavity-frequency-doubled CW Nd:YAG laser by compensating for thermal lensing of a KTP crystal and Nd:YAG rods [J] . Kojima T., Fujikawa S. IEEE Journal of Quantum Electronics . 1999,第3期

机译：通过补偿KTP晶体和Nd：YAG棒的热透镜效应，稳定大功率二极管侧泵腔内倍频CW Nd：YAG激光器
2. Stabilization of a high-power diode-side-pumpedintracavity-frequency-doubled CW Nd:YAG laser by compensating forthermal lensing of a KTP crystal and Nd:YAG rods [J] . Kojima T., Fujikawa S., Yasui K. IEEE Journal of Quantum Electronics . 1999,第3期

机译：通过补偿KTP晶体和Nd：YAG棒的热透镜，稳定大功率二极管侧泵浦倍频倍频CW Nd：YAG激光器
3. High-efficiency high-power QCW diode-side-pumped zigzag Nd:YAG ceramic slab laser [J] . Y. Chen, W. Liu, Y. Bo, Applied physics . 2013,第1期

机译：高效大功率QCW二极管侧泵曲折Nd：YAG陶瓷平板激光器
4. High Power Performance and Stability Analysis of a Diode-Side-Pumped Intracavity-Frequency-Doubled CW Nd:YAG Laser [C] . Tetsuo Kojima, Shuichi Fujikawa, Koji Yasui Advanced Solid State Lasers . 1998

机译：二极管侧泵腔内频率翻倍的CW Nd：YAG激光器的高功率性能和稳定性分析
5. MICROSTRUCTURAL AND COMPOSITIONAL EFFECTS ON THE THERMAL DIFFUSIVITY OF SILICON-CARBIDE AND SILICON-NITRIDE COMPOSITES (CERAMIC, THERMAL CONDUCTIVITY, PULSE METHOD, LASER FLASH) [D] . BENTSEN, LARRY D. 1984

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6. Correlation between the operation time using two different power settings of a Ho: YAG laser: laser power doesn’t influence lithotripsy time [O] . Takashi Kawahara, Hiroki Ito, Hideyuki Terao, 2013

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7. Stabilization of High-Power Intracavity-Frequency-Doubled Solid-State Laser by Advanced Resonator Design in Consideration of Thermal Lensing of Nonlinear Crystal. [O] . Tetsuo KOJIMA, Koji YASUI 1998

机译：考虑到非线性晶体热透镜的先进谐振器设计稳定高功率腔内频率加倍固态激光器。

The influence of KTP's thermal effects on the stabilization of a high- power diode-side-pumped all-solid-state QCW intracavity-frequency-doubled Nd:YAG laser and the compensating methods

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