光学
色散(光学)
光纤激光器
光纤
红外线的
激光器
材料科学
偏振模色散
孤子
色散位移光纤
光电子学
物理
光纤传感器
非线性系统
量子力学
作者
Xuan Wang,Jichen Pan,Chuanfei Yao,Xuelian Yang,Yang Ying,Yamin Liu,Pingxue Li
标识
DOI:10.1109/jlt.2025.3530505
摘要
High-power mid-infrared (MIR) lasers have aroused great interest in many scientific and industrial applications. Due to the immaturity of pump sources and fiber materials, it has been difficult to achieve high-power laser output in MIR long-wavelength spectrum (LWS) exceeding 2.4 μm using traditional schemes. Here, we propose a new method for generating MIR laser that utilizes the dispersion characteristics of nonlinear fiber to segmentally regulate the frequency-shift, accumulation, and enhancement process of soliton group pulses, in order to maximize pump energy conversion and reshape spectral profile. A 14.72 W high-power all-fiber MIR laser was obtained using a fluorotellurite fiber with dispersion specifically engineered as a frequency-shift stretcher. The laser conversion efficiency reached 70%, facilitating efficient energy conversion from 2 μm near-infrared laser to 3 μm mid-infrared laser. Notably, the proportion of MIR LWS exceeding 2.4 μm was significantly enhanced, accounting for over 90% of the total spectrum components. This work provides a simple, compact, efficient, stable and economical method for developing high-power, high-efficiency, and high-occupancy MIR fiber lasers, without the need for complex MIR amplification systems, which is of great scientific significance for promoting the practical application of 3–5 μm MIR light sources.
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