New thin disk laser materials: Yb:ScYLO and Yb:YLF

K. Beil, S. T. Fredrich-Thornton, C. Krãnkel, K. Petermann, D. Parisi, M. Tonelli, G. Huber
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引用次数: 8

Abstract

The thin disk laser is a well-established setup for lasers with high output powers in continuous wave as well as in pulsed operation mode [1]. The most common gain material for the thin disk laser is Yb:YAG. In order to obtain even higher output powers an increased thermal conductivity is beneficial. One solution to obtain higher thermal conductivities of the gain material is to substitute the Y-ion with the Lu-ion. We have shown that in such gain materials like Yb:LuAG [2] or Yb:Lu2O3 [3], the thermal conductivity remains high even for high Yb-doping concentrations. Another solution to improve the heat removal is to reduce the thickness of the gain material. To maintain a good absorption in this case, high doping concentrations are necessary. However, it has been shown that efficient laser operation cannot be achieved in Yb:YAG for more than 15% Yb-doping concentration. Also in terms of the achievable pulse duration in modelocked operation, Yb:YAG is not the best choice due to its limited gain bandwidth. For this purpose mixed gain materials like Yb:LuScO3 have been shown to be very suitable [4].
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新型薄盘激光材料:Yb:ScYLO和Yb:YLF
对于连续波和脉冲工作模式下具有高输出功率的激光器,薄板激光器是一种完善的设置[1]。薄板激光器最常用的增益材料是Yb:YAG。为了获得更高的输出功率,增加导热系数是有益的。获得高导热增益材料的一种解决方法是用Lu-ion代替Y-ion。我们已经证明,在像Yb:LuAG[2]或Yb:Lu2O3[3]这样的增益材料中,即使在高镱掺杂浓度下,热导率仍然很高。另一种提高散热性能的方法是减小增益材料的厚度。在这种情况下,为了保持良好的吸收,高的掺杂浓度是必要的。然而,已有研究表明,当Yb掺杂浓度超过15%时,Yb:YAG无法实现高效的激光操作。此外,在模型锁定操作中可实现的脉冲持续时间方面,由于其有限的增益带宽,Yb:YAG不是最佳选择。为此目的,混合增益材料如Yb:LuScO3已被证明是非常合适的[4]。
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