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可见光波段激光在生物、医学、探测等领域有着重要应用,相较于传统非线性倍频得到可见光激光,可以利用稀土元素Pr3+、Sm3+、Tb3+、Dy3+等掺杂来制备直接输出可见光的激光晶体。对于黄光波段激光,晶体掺杂Dy3+更为合适。目前,掺杂Dy3+的激光晶体多是处于理论阶段,激光实验成功的案例较少。近段时间,生长出的高质量Dy3+掺杂的硼酸盐晶体Gd Mg B_5O10(Dy:GMB)被报道成功研制出发射580 nm黄光波段的激光器。使用中国科学院福建物质结构研究所制备的3 mm×3 mm×20 mm的Y-cut Dy:GMB晶体,利用444 nm蓝光LD泵浦搭建平平腔激光器得到了波长为579.3 nm的激光输出。通过使用不同透过率的输出耦合镜比较,得到最大输出功率为161 mW,斜效率为3.7%的黄光激光输出,不仅与初次实验报道进行了比较验证,并提出了改进方法,从而有利于继续挖掘Dy:GMB晶体在黄光波段激光的潜力。
Abstract:Introduction Visible-light lasers have applications in biology, medicine, and detection. Compared to conventional nonlinear frequency doubling methods for obtaining visible light lasers, it is possible to prepare laser crystals that directly emit a visible light via doping with rare-earth elements such as Pr3+, Sm3+, Tb3+, and Dy3+. For yellow light lasers, doping with Dy3+ is more suitable. The existing Dy3+-doped laser crystals are still at the theoretical stage, with a few experimental cases. Recently, a high-quality Dy3+-doped borate crystal GdMgB_5O10(Dy3+:GMB) is prepared to produce a yellow light laser at a wavelength of 580 nm. In this study, a plane-plane cavity laser was assembled using a 3 mm×3 mm×20 mm Y-cut Dy3+:GMB crystal with a 444 nm blue LD pump, achieving a laser output at 579.3 nm. The maximum output power reached 161 mW with a slope efficiency of 3.7% as using different output couplers at different transmission rates. Methods In this experiment, a 444 nm blue LD with a maximum power of 12 W was used as a pump source. The model of the blue LD pump was LSR444CP4-12W. The pump output a spatial light directly without fiber coupling and used air cooling to maintain a temperature of 25 ℃. The beam size at the output of the pump was 4.3 mm horizontally and 4.1 mm vertically. The beam remained parallel within 0.5 m and could be approximated as a parallel light. A plano-convex lens with a focal length of 150 mm was used. A Y-cut Dy:GMB crystal with the dimensions of 3 mm×3 mm×20 mm was used. The doping concentration of Dy3 in the crystal was 6.08%, and the end faces of the crystal were polished but not coated for the blue wavelength band. The Dy:GMB crystal was wrapped in indium foil and placed in a water-cooled copper block, with the copper block's water cooling set to 20 ℃. The polarization direction of the pump light was vertical. Based on the polarization bsorption efficiency of the Dy:GMB crystal along different axes, the crystal was positioned in an optical path. The pump light absorption efficiency of the crystal was measured under non-lasing conditions. When the crystal was placed, the pump light absorption efficiency was 55%. The laser resonator consisted of two coated plane mirrors. IM was the input mirror for the pump light, with coating arameters that could reduce reflection and increase transmission at 444 nm. The measured transmission at 444 nm was 96%. It also had a high reflectivity at 579 nm with a reflectivity of ≥99.8%. OC was the output coupler mirror, and the coated mirrors with 579 nm transmission rates of 1% and 2% were used. A long-pass edge filter with a cutoff wavelength of 450 nm was placed at the laser output to effectively reduce the impact of pump light on power measurements. After the output power measurement, a Glan prism was used to analyze the polarization of the output laser. Results and discussion The output wavelength of the experimental laser is 579.3 nm, without other wavelengths detected. In the experiment with an OC transmission rate of 1%, a laser generation begins when the crystal absorbes 1.94 W of pump power, achieving a maximum output power of 161 mW and a slope efficiency of 3.7%. In the experiment with an OC transmission rate of 2%, a laser generation starts at an absorption power of 2.81 W, having a maximum output power of 129 m W with a slightly lower slope efficiency of 3.6%. No saturation in laser output power occurs in either set of experiments. The laser threshold and output power using an OC transmission rate of 1% are slightly greater than those using an OC transmission rate of 2%, which is consistent with the results reported in a previous study. Based on the slope efficiency, it is estimated that under the same pump absorption power, the maximum output power of the laser in this experiment can exceed 628 mW. There are three methods to improve the output power and slope efficiency of the laser via comparing the performance of the crystal in two separate experiments. The first method is to use a higher-power and higher-quality pump to enhance the absorption efficiency of the Dy:GMB crystal. The second method is to employ different types of laser cavities and optimize the coating parameters of the IM and OC, as well as shape the pump beam to achieve better spatial mode matching between the pump light and the laser cavity. The third method is to optimize the growth process to obtain X-cut or Z-cut crystals of sufficient length with varying Dy doping concentrations, as the emission cross-section of the Dy:GMB crystal is maximum at 578.5 nm along the E//Y direction. Conclusions A 579.3 nm yellow laser output with a maximum power of 161 mW and a slope efficiency of 3.7% was obtained using a plane-plane cavity laser setup with Dy:GMB crystal pumped by a 444 nm blue LD. An application potential of the crystal could be achieved via comparing the initial laser experiments with the same crystal using blue LDs at different wavelengths. This study could provide insights for future improvements in the output power and slope efficiency of lasers constructed with Dy:GMB crystals.
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基本信息:
DOI:10.14062/j.issn.0454-5648.20240716
中图分类号:TN248
引用信息:
[1]潘圣元,江泽茜,黄溢声,等.激光二极管泵浦黄光掺镝硼酸钆镁激光器[J].硅酸盐学报,2025,53(12):3461-3467.DOI:10.14062/j.issn.0454-5648.20240716.
基金信息:
国家重点研发计划(2022YFB3605703); 国家自然科学基金(U21A20508,62105334); 中国科学院青年创新促进会项目(2022303);中国科学院技术支撑人才专项(2022000061);中国科学院科研仪器设备研制项目(YZLY202001);中国科学院海西研究院自主部署项目(CXZX-2023-JQ01,CXZX-2022-GH09); 中国福建光电信息科学与技术创新实验室项目(2024CXY108,2020ZZ108,2021ZZ118)