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Generation of high-energy self-mode-locked pulses in a Tm-doped fiber laser

Jiancheng Zheng, Jinyu Xie, Qingqing Liu, Chaojian He, Yaoyao Qi, Li Li, Lihong He, Chibiao Liu, Xuechun Lin, Song Yang

2024Applied Physics Letters17 citationsDOI

Abstract

The incorporation of a material-based or artificial saturable absorber into a fiber laser cavity imposes a limitation on energy enhancement owing to its low damage threshold and high environmental sensitivity. To address this issue, one promising alternative approach is the utilization of the self-mode-locking technique. Here, we present a robust self-mode-locked Tm-doped fiber laser with high pulse energy emission. A simple and compact fiber laser structure is realized by utilizing a section of a Tm-doped fiber, serving both as a gain medium and a saturable absorber. Thus, the operational stability is enhanced, especially under high-energy conditions. Furthermore, the realization of high-energy pulses is accomplished through the integration of dispersion management technique. Experimental results reveal that the maximum single-pulse energy increases from 34.8 pJ to 120.2 nJ as the round-trip group delay dispersion decreases from −0.43 to −12.40 ps2. The proposed self-mode-locked Tm-doped fiber laser under high-energy operation exhibits remarkable performance. Our results provide a simple approach to obtaining a mid-infrared laser source with high pulse energy and hold significant potential for advancing high-energy laser systems.

Topics & Concepts

Fiber laserMaterials scienceSaturable absorptionLaserOptoelectronicsOpticsFiberInjection seederDispersion (optics)DopingPulse (music)Mode-lockingEnergy (signal processing)Laser power scalingPhysicsComposite materialQuantum mechanicsDetectorWavelengthAdvanced Fiber Laser TechnologiesPhotonic Crystal and Fiber OpticsLaser-Matter Interactions and Applications