Investigation of a 100 W Solar-Pumped Disk Laser with TEM00 Output

Pub Date : 2023-11-23 DOI:10.1007/s10946-023-10178-y
Biqing Wang, Lanling Lan, Yan Liu, Yulong Tang, Yuanyuan Zhang
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Abstract

To improve the output power of solar-pumped lasers, we propose a new configuration of solar disk laser. A rotating parabolic reflector acts as the primary concentrator with top and bottom radii of 1600 and 600 mm, respectively. The incident sunlight is reflected by the primary concentrator to the inlet of the heteromorphic compound parabolic concentrator (HCPC) and is absorbed by the gain medium after multiple reflection. The diameter, thickness, and doping concentration of the Nd :YAG disk are 20 mm, 1 mm, and 1.0 at.%, respectively. The two surfaces of the disk are cooled by heavy water. Owing to the increased surface area of the disk for receiving sunlight, solar absorption by the gain medium is greatly improved. Ray tracing shows that maximum absorbed solar power by the Nd :YAG disk can reach 446 W through optimizing the HCPC. Solving rate equations, we obtain the laser output power in the TEM00 mode as high as ∼123 W, with a conversion efficiency of ∼27%. In addition, we analyze the temperature distribution of the solar-pumped Nd :YAG disk laser. The design of this solar concentrating system and the over-hundred-watts disk laser provides a new idea for further scaling the output power of solar-pumped solid-state lasers.

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研究具有 TEM00 输出的 100 W 太阳能泵浦碟形激光器
为了提高太阳能泵浦激光器的输出功率,我们提出了一种新的太阳盘激光器配置。旋转抛物面反射器作为主聚光器,其上下半径分别为 1600 毫米和 600 毫米。入射太阳光由主聚光器反射到异形复合抛物面聚光器(HCPC)的入口,经过多次反射后被增益介质吸收。Nd :YAG 圆盘的直径、厚度和掺杂浓度分别为 20 毫米、1 毫米和 1.0 at.%。圆盘的两个表面由重水冷却。由于圆盘接收太阳光的表面积增大,增益介质对太阳光的吸收率大大提高。光线跟踪显示,通过优化 HCPC,Nd :YAG 盘吸收的最大太阳光功率可达 446 W。通过求解速率方程,我们得到 TEM00 模式下的激光输出功率高达 ∼123 W,转换效率为 ∼27%。此外,我们还分析了太阳能泵浦 Nd :YAG 盘式激光器的温度分布。该太阳能聚光系统和过百瓦盘式激光器的设计为进一步扩大太阳能泵浦固体激光器的输出功率提供了新思路。
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