Gaida C, Gebhardt M, Stutzki F, Jauregui C, Limpert J, Tünnermann A
Opt Lett. 2015 Nov 15;40(22):5160-3. doi: 10.1364/OL.40.005160.
We report on the experimental realization of a compact, fiber-based, ultrashort-pulse laser system in the 2 μm wavelength region delivering 24 fs pulse duration with 24 MW pulse peak power and 24.6 W average power. This performance level has been enabled by the favorable quadratic wavelength-dependence of the self-focusing limit, which has been experimentally verified to be at approximately 24 MW for circular polarization in a solid-core fused-silica fiber operated at a wavelength around 2 μm. The anomalous dispersion in this wavelength region allows for a simultaneous nonlinear spectral broadening and temporal pulse compression. This makes an additional compression stage redundant and facilitates a very simple and power-scalable approach. Simulations that include both the nonlinear pulse evolution and the transverse optical Kerr effect support the experimental results.
我们报道了在2μm波长区域实现的一种紧凑的、基于光纤的超短脉冲激光系统,其脉冲持续时间为24 fs,脉冲峰值功率为24 MW,平均功率为24.6 W。这种性能水平得益于自聚焦极限有利的二次波长依赖性,实验验证在波长约2μm的实芯熔石英光纤中,圆偏振时自聚焦极限约为24 MW。该波长区域的反常色散允许同时进行非线性光谱展宽和时间脉冲压缩。这使得额外的压缩阶段变得多余,并促进了一种非常简单且可功率扩展的方法。包括非线性脉冲演化和横向光学克尔效应的模拟结果支持了实验结果。
