中国激光, 2021, 48 (4): 0401010, 网络出版: 2021-02-03   

高功率GTWave光纤激光器研究进展 下载: 2174次

Research Progress on High-Power GTWave Fiber Lasers
黄值河 1,2,3,*曹涧秋 1,2,3,**陈金宝 1,2,3,*
作者单位
1 国防科技大学前沿交叉学科学院, 湖南 长沙 410073
2 高能激光技术湖南省重点实验室, 湖南 长沙410073
3 大功率光纤激光湖南省协同创新中心, 湖南 长沙410073
摘要
高功率GTWave光纤激光器是目前光纤激光器研究的一个热点。介绍了GTWave光纤的结构,并回顾了国内外高功率GTWave光纤激光器的研究成果,可以看出,国内外GTWave光纤激光器的发展极其迅猛,其功率扩展能力非常强、结构设计非常灵活,输出功率远高于其他光纤激光器;同时,对比分析了高功率GTWave光纤激光器的特点和优势,并对今后的研究进行了展望。
Abstract

Significance High-power fiber lasers offer many advantages: high-power output, excellent beam quality, high optical efficiency, high degree of integration, high reliability, and spatial compactness. Fiber lasers have therefore been widely adopted for both scientific and commercial applications including material processing, free space communication, and military defense. Among the different kinds of fiber laser, the GTWave is especially popular for its significant power scalability and flexible structure design. This paper reviews the results of high-power GTWave fiber lasers across the world; their characteristics and merits are analyzed through comparison with conventional double cladding fiber lasers. Future directions of research on GTWave fiber lasers are additionally discussed.

Progress The construction of GTWave fiber is detailed in Fig.1 of this paper. The results of high-power GTWave fiber lasers all over the world, shown in Table 1, indicate that most of the results are made by four organizations: Southampton Photonics Inc., the IPG Photonics Corporation, China’s National University of Defense Technology, and the China Academy of Engineering Physics.

The concept of using optical fibers to evanescently couple pump energy from laser diodes to a solid-state laser rod was proposed by U.S. Naval Research Laboratory in 1991, but the University of Southampton made the first GTWave fiber, and Southampton Photonics Inc. manufactured many high-power fiber lasers that demonstrated the high injected pump power and high-power scalability of GTWave fiber lasers. Southampton Photonics Inc. manufactured a 2 kW GTWave fiber oscillator in 2016; its stimulated Raman scattering (SRS) level was low, and the transverse mode instability (TMI) had been mitigated. The IPG Photonics Corporation also developed GTWave fiber very early, and manufactured a 2 kW fiber laser in 2006, which showed the flexible structure design of GTWave fiber and displayed massive injected pump power. They created the first 10 kW high-power GTWave fiber laser in 2009, which was much more powerful than other fiber lasers. The Chinese National University of Defense Technology developed a homemade 1 kW GTWave fiber laser in 2014, and obtained a 4 kW GTWave fiber oscillator and main oscillator power amplifier (MOPA) by multi-stage bidirectional pumping in 2018. Although the China Academy of Engineering Physics’ research on GTWave fiber started relatively late, they adopted multi-pump fiber schemes to develop GTWave fiber and developed a (2+1) GTWave fiber 2 kW MOPA laser in 2016. They obtained a 10.45 kW (8+1) GTWave fiber MOPA laser in 2018.

Many other organizations have paid much attention to GTWave fiber lasers; however, the technology requires much investment and technology, and as a result most can do only theoretical research. The Russian Academy of Sciences developed a 100 W GTWave fiber laser in 2005, and made many low-power fiber components in early years, but no results have been reported of late.

Conclusion and Prospect The above research shows that the development of GTWave fiber lasers is very fast, and that their power scalability is so strong that their output power is much higher than that of other fiber lasers. The output power of GTWave fiber has grown to 10 kW within 10 years. We analyze the characteristics and merits of GTWave fiber lasers through comparison with conventional double cladding fiber lasers. Although the conventional double cladding fiber laser has exceeded 5 kW for the reverse combiners commercialized in recent years, GTWave fiber lasers are still more suitable for bidirectional pumping and multi-injected ports by means of multi-stage cascaded amplifiers or multi-pump fiber schemes. As the pump light is coupled gradually to the active GTWave fiber, the heat is well-distributed along the fiber, which is more suitable for a high-power fiber laser.

The development process of GTWave fiber is very complicated, and the price is very high at present. This limits the research of GTWave fiber lasers to only a few organizations. With the development of high-power fiber lasers, people have paid more attention to GTWave fiber both theoretically and experimentally. We believe that the commercialization of GTWave fiber will come in the near future, as more and more people conduct research on GTWave fiber lasers.

黄值河, 曹涧秋, 陈金宝. 高功率GTWave光纤激光器研究进展[J]. 中国激光, 2021, 48(4): 0401010. Zhihe Huang, Jianqiu Cao, Jinbao Chen. Research Progress on High-Power GTWave Fiber Lasers[J]. Chinese Journal of Lasers, 2021, 48(4): 0401010.

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