Miniaturization of high beam quality 1.543 μm Raman laser with backward stimulated Raman scattering

IF 2.2 3区 物理与天体物理 Q2 OPTICS
Feiyu Qian , Xianglong Cai , Shutong He , Jinglu Sun , Ming Xu , Yuxi Jia , Zhensong Liu , Yannan Tan , Wanfa Liu , Jingwei Guo
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Abstract

It is very challenging to make high peak power (big pulse energy) Raman lasers compact, due to laser induce breakdown (LIB) effect; and it is even more difficult to achieve a decent beam quality meanwhile. In this work, a pulsed 1064 nm laser was used as pump source; pressurized methane was used as Raman active medium, which had the largest ratio of backward/forward Raman gain coefficient among all gaseous media; and backward first Stokes (BS1) Raman laser of 1543 nm with good beam quality was realized. When an f=0.5 m lens was used to focus pump beam into a 0.9 m long Raman cell filled with 3.5 MPa methane, 276.1 mJ BS1 was achieved, the corresponding photon conversion efficiency was 70.8% and the peak power was 83.7 MW. BS1 beam quality was measured to be Mx2=2.54,My2=2.28, which was significantly better than that of pump laser. In a setup of f=0.3 m focal lens and 0.5 m long Raman cell, 197.8 mJ BS1 was achieved, with the company of serious LIB. In order to meliorate LIB and improve BS1 conversion efficiency, the focal lens was tilted by 20°, pump laser beam waist and depth of focus increased significantly, BS1 was improved to 225.0 mJ, the corresponding photon conversion efficiency was 58.5%. An even short focal lens and Raman cell with reasonable BS1 energy was possibly achieved by tilting a shorter focal lens by a larger angle. This work also demonstrated that the increment of BS1 conversion may help to reduce the effect of LIB on SRS process.
利用后向受激拉曼散射实现高光束质量 1.543 μm 拉曼激光器的微型化
由于激光诱导击穿效应(LIB)的影响,要使高峰值功率(大脉冲能量)的拉曼激光器结构紧凑非常具有挑战性;同时,要获得良好的光束质量更是难上加难。在这项工作中,我们使用 1064 nm 脉冲激光器作为泵浦源;使用加压甲烷作为拉曼活性介质,它在所有气体介质中具有最大的后向/前向拉曼增益系数比;实现了具有良好光束质量的 1543 nm 后向第一斯托克斯(BS1)拉曼激光器。当使用 f=0.5 m 的透镜将泵浦光束聚焦到充满 3.5 MPa 甲烷的 0.9 m 长拉曼池时,实现了 276.1 mJ BS1,相应的光子转换效率为 70.8%,峰值功率为 83.7 MW。测得的 BS1 光束质量为 Mx2=2.54,My2=2.28, 明显优于泵浦激光器的光束质量。在 f=0.3 m 焦距透镜和 0.5 m 长拉曼池的装置中,在严重 LIB 的陪伴下,实现了 197.8 mJ BS1。为了改善 LIB 并提高 BS1 转换效率,焦镜头倾斜了 20°,泵浦激光光束腰和聚焦深度显著增加,BS1 提高到 225.0 mJ,相应的光子转换效率为 58.5%。如果将更短的聚焦透镜倾斜更大的角度,就有可能实现更短的聚焦透镜和具有合理 BS1 能量的拉曼池。这项工作还证明,提高 BS1 转换率有助于减少 LIB 对 SRS 过程的影响。
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来源期刊
Optics Communications
Optics Communications 物理-光学
CiteScore
5.10
自引率
8.30%
发文量
681
审稿时长
38 days
期刊介绍: Optics Communications invites original and timely contributions containing new results in various fields of optics and photonics. The journal considers theoretical and experimental research in areas ranging from the fundamental properties of light to technological applications. Topics covered include classical and quantum optics, optical physics and light-matter interactions, lasers, imaging, guided-wave optics and optical information processing. Manuscripts should offer clear evidence of novelty and significance. Papers concentrating on mathematical and computational issues, with limited connection to optics, are not suitable for publication in the Journal. Similarly, small technical advances, or papers concerned only with engineering applications or issues of materials science fall outside the journal scope.
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