Ultrafast dissipative soliton generation in anomalous dispersion achieving high peak power beyond the limitation of cubic nonlinearity

IF 15.7 Q1 OPTICS
Jinhwa Gene, Seung Kwan Kim, Sun Do Lim, Min Yong Jeon
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Abstract

Abstract The maximum peak power of ultrafast mode-locked lasers has been limited by cubic nonlinearity, which collapses the mode-locked pulses and consequently leads to noisy operation or satellite pulses. In this paper, we propose a concept to achieve mode-locked pulses with high peak power beyond the limitation of cubic nonlinearity with the help of dissipative resonance between quintic nonlinear phase shifts and anomalous group velocity dispersion. We first conducted a numerical study to investigate the existence of high peak power ultrafast dissipative solitons in a fiber cavity with anomalous group velocity dispersion (U-DSAD) and found four unique characteristics. We then built long cavity ultrafast thulium-doped fiber lasers and verified that the properties of the generated mode-locked pulses match well with the U-DSAD characteristics found in the numerical study. The best-performing laser generated a peak power of 330 kW and a maximum pulse energy of 80 nJ with a pulse duration of 249 fs at a repetition rate of 428 kHz. Such a high peak power exceeds that of any previous mode-locked pulses generated from a single-mode fiber laser without post-treatment. We anticipate that the means to overcome cubic nonlinearity presented in this paper can give insight in various optical fields dealing with nonlinearity to find solutions beyond the inherent limitations.

Abstract Image

超限三次非线性的超高速耗散孤子产生,达到峰值功率
摘要超快锁模激光器的最大峰值功率受到三次非线性的限制,使锁模脉冲崩溃,从而导致噪声工作或卫星脉冲。本文提出了一种利用五次非线性相移和反常群速度色散之间的耗散共振来实现超越三次非线性限制的峰值功率高的锁模脉冲的概念。本文首先对具有异常群速度色散(U-DSAD)的光纤腔中存在的峰值功率超快耗散孤子进行了数值研究,发现了四个独特的特性。然后,我们构建了长腔超快掺铥光纤激光器,并验证了所产生的锁模脉冲的特性与数值研究中发现的U-DSAD特性很好地匹配。在428 kHz的重复频率下,激光器产生的峰值功率为330 kW,最大脉冲能量为80 nJ,脉冲持续时间为249 fs。如此高的峰值功率超过了以往任何未经后处理的单模光纤激光器产生的锁模脉冲。我们期望本文提出的克服三次非线性的方法可以为处理非线性的各种光学领域提供洞察力,以找到超越固有局限性的解决方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
25.70
自引率
0.00%
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0
审稿时长
13 weeks
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