Double harmonic mode-locking in soliton fiber ring laser acquired through the resonant optoacoustic coupling

IF 5.4 1区 物理与天体物理 Q1 OPTICS APL Photonics Pub Date : 2024-05-13 DOI:10.1063/5.0195623
V. A. Ribenek, P. A. Itrin, D. A. Korobko, A. A. Fotiadi
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Abstract

Passive harmonic mode-locking of a soliton fiber laser locked to optoacoustic resonance (OAR) in the cavity fiber ensures high-frequency laser operation, high pulse stability, and low timing jitter. However, the pulse repetition rate (PRR) of such lasers is limited to ∼1 GHz for standard fibers due to the available acoustic modes. Here, we address these limitations by demonstrating a soliton fiber laser built from standard fiber components and subjected to double harmonic mode-locking (DHML). As an example, the laser adjusted to operate at the 15th harmonic of its cavity matching the OAR at ∼199 MHz could be driven to operate at a high harmonic of this particular OAR frequency, thus reaching ∼12 GHz. This breakthrough is made possible through controllable optoacoustic interactions in a short, 50 cm segment of unjacketed cavity fiber. We propose that the precise alignment of the laser cavity harmonic and fiber acoustic modes leads to a long-lived narrow-band acoustic vibration. This vibration sets the pace for the pulses circulating in the cavity by suppressing modes that do not conform to the Vernier principle. The surviving modes, equally spaced by the OAR frequency, in cooperation with the gain depletion and recovery mechanism, facilitate the formation of stable high-frequency pulse sequences, enabling DHML. In this process, the OAR rather than the laser cavity defines the elementary step for laser PRR tuning. Throughout the entire PRR tuning range, the soliton fiber laser exhibits enhanced stability, demonstrating supermode suppression levels better than ∼40 dB and picosecond pulse timing jitter.
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通过谐振光声耦合获得孤子光纤环形激光器中的双谐波锁模
孤子光纤激光器的被动谐波锁模锁定腔光纤中的光声共振(OAR),可确保激光器的高频率运行、高脉冲稳定性和低定时抖动。然而,由于可用声学模式的限制,这种激光器的脉冲重复率(PRR)在标准光纤中只能达到 ∼ 1 GHz。在此,我们展示了一种由标准光纤元件制成的孤子光纤激光器,并对其进行了双谐波模式锁定(DHML),从而解决了这些限制。举例来说,将激光器调整为在与频率为 199 MHz 的 OAR 相匹配的腔体的第 15 次谐波下工作,就能驱动激光器在这一特定 OAR 频率的高次谐波下工作,从而使频率达到 12 GHz。这一突破是在一段 50 厘米短的无套管空腔光纤中通过可控光声相互作用实现的。我们提出,激光腔谐波和光纤声学模式的精确对准导致了长寿命的窄带声学振动。这种振动通过抑制不符合维尼尔原理的模式,为在腔体内循环的脉冲设定了节奏。与 OAR 频率间隔相等的幸存模式与增益损耗和恢复机制合作,促进了稳定的高频脉冲序列的形成,从而实现了 DHML。在这个过程中,OAR 而不是激光腔决定了激光 PRR 调谐的基本步骤。在整个 PRR 调谐范围内,孤子光纤激光器表现出更高的稳定性,超模抑制水平优于 ∼ 40 dB,脉冲定时抖动为皮秒级。
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来源期刊
APL Photonics
APL Photonics Physics and Astronomy-Atomic and Molecular Physics, and Optics
CiteScore
10.30
自引率
3.60%
发文量
107
审稿时长
19 weeks
期刊介绍: APL Photonics is the new dedicated home for open access multidisciplinary research from and for the photonics community. The journal publishes fundamental and applied results that significantly advance the knowledge in photonics across physics, chemistry, biology and materials science.
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