Modeling In-band Pumped kW Level High-Power Tm-Doped Fiber Lasers via Simulations

Mengmeng Tao; Xisheng Ye; Jingfeng Ye; Ting Yu; Zhao Quan; Yunfeng Qi; Guobin Feng; Weibiao Chen

doi:10.3788/CJL202249.0101019

Journals >Chinese Journal of Lasers >Volume 49 >Issue 1 >Page 0101019 > Article

Chinese Journal of Lasers
Vol. 49, Issue 1, 0101019 (2022)

Modeling In-band Pumped kW Level High-Power Tm-Doped Fiber Lasers via Simulations

Mengmeng Tao^1、2、**, Xisheng Ye^1、*, Jingfeng Ye², Ting Yu¹, Zhao Quan¹, Yunfeng Qi¹, Guobin Feng², and Weibiao Chen¹

Author Affiliations

¹Shaihai Key Laboratory of All Solid-State Laser and Applied Techniques, Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Shanghai 201800, China

²State Key Laboratory of Laser Interaction with Matter, Northwest Institute of Nuclear Technology, Xi’an, Shaanxi 710024, China

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DOI: 10.3788/CJL202249.0101019 Cite this Article Set citation alerts

Mengmeng Tao, Xisheng Ye, Jingfeng Ye, Ting Yu, Zhao Quan, Yunfeng Qi, Guobin Feng, Weibiao Chen. Modeling In-band Pumped kW Level High-Power Tm-Doped Fiber Lasers via Simulations[J]. Chinese Journal of Lasers, 2022, 49(1): 0101019 Copy Citation Text

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Abstract

Conclusions

Performance and power scalability of resonantly pumped Tm-doped fiber systems are theoretically investigated. Simulations demonstrate that the 1.9 μm resonant pedestal pump provides high-power Tm-doped fiber systems with a high operation efficiency of >90%, resulting in a controllable heat waste (within 10% of the output). This limited heat greatly relieves the thermal effects inside the active fiber, eliminating transversal mode instability as a major concern for power scaling of Tm-doped fiber systems. For the widely exploited 25/250 double-clad TDF, the 10-kW-level output is attainable with the 1.9 μm resonant pump.

Keywords

fiber laser heat load in-band pump lasers power scaling thermal effects