水平定向结晶法生长浓度渐变Yb∶YAG激光晶体及光谱性能研究

摘要/Abstract

摘要： 本文采用水平定向结晶(HDC)法成功生长出180 mm×81 mm×16 mm的浓度渐变Yb∶YAG激光晶体,从放肩部位和尾部分别获取了尺寸为40 mm×40 mm×7 mm、70 mm×70 mm×7 mm的Yb∶YAG激光晶体板条各两件。采用632 nm激光、偏光应力仪对晶体板条的光学性质进行检测,实验结果发现靠近晶坯自由表面的板条内部通透,无散射光路,应力较小且分布均匀,表明该晶体板条具有优异的光学质量。进一步测试分析了晶体板条不同位置处的吸收光谱,根据935 nm波长处的吸收系数计算出Yb³⁺的掺杂浓度,发现40 mm×40 mm×7 mm的激光晶体板条中Yb³⁺掺杂浓度沿晶体生长方向逐步增加,浓度梯度约为0.42%/cm;而70 mm×70 mm×7 mm的激光晶体板条中Yb³⁺掺杂浓度几乎保持不变,约为4.50%。

关键词: 浓度渐变, 光谱性能, Yb∶YAG, 水平定向结晶法, 激光晶体

Abstract: A concentration gradient Yb∶YAG laser crystal with a size of 180 mm×81 mm×16 mm was grown by horizontal directional crystallization (HDC) method. Four crystal pieces with the size of 40 mm×40 mm×7 mm and 70 mm×70 mm×7 mm (two pieces for each size) were taken from the shoulders and tails of the single crystal plate, respectively. A 632 nm laser and a polarizing stress meter was used to characterize the samples’ optical properties. From the results, it can be seen that compared to the crystals near the crucible, the crystals near the surface are more transparent, with no scattering light path, and showing lower and more uniform stress. The crystal was also subjected to absorption spectra measurement, and its absorption coefficient at 935 nm wavelength was used to calculate the doping concentration of Yb³⁺ at different positions in the crystal. It was found that the Yb³⁺ doping concentration in laser crystal plates with a size of 40 mm×40 mm×7 mm gradually increased along the crystal growth direction, with a concentration gradient of approximately 0.42%/cm. The Yb³⁺ doping concentration in laser crystal plate with a size of 70 mm×70 mm×7 mm remains almost unchanged, which is approximately 4.50%.

Key words: concentration gradient, spectral property, Yb∶YAG, horizontal directional crystallization method, laser crystal

中图分类号:

丁雨憧, 张灵, 李海林, 张月, 唐杨, 强铭, 林辉. 水平定向结晶法生长浓度渐变Yb∶YAG激光晶体及光谱性能研究[J]. 人工晶体学报, 2024, 53(10): 1688-1698.

DING Yuchong, ZHANG Ling, LI Hailin, ZHANG Yue, TANG Yang, QIANG Ming, LIN Hui. Spectral Properties of Concentration Gradient Yb∶YAG Laser Crystals Grown by Horizontal Directional Crystallization Method[J]. JOURNAL OF SYNTHETIC CRYSTALS, 2024, 53(10): 1688-1698.

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