振荡-放大一体化光纤激光器研究进展OA
Research progress on oscillating-amplifying integrated fiber lasers
振荡-放大一体化光纤激光器因其兼具振荡器结构简单、抗反射性能优异及放大器高效率等优势,在高功率激光领域展现出广阔的应用前景.从理论研究和实验研究两个维度综述了振荡-放大一体化光纤激光器的最新研究进展.在理论研究层面,重点梳理了包含模式不稳定效应及非线性效应的理论模型研究进展;在实验研究层面,按波长维度的常规波段、短波长、超连续谱归纳了单端输出振荡-放大一体化光纤激光器的研究成果,并梳理了双端输出结构的最新进展.基于上述分析,指出当前在理论模型普适性局限与系统性实验研究的不足,并对未来发展方向进行了展望.
Oscillating-amplifying integrated fiber lasers(OAIFLs)have emerged as a promising technology in high-power laser applications by combining the structural simplicity and superior anti-reflection capability of oscillators with the high efficiency of amplifiers.This review systematically summarizes recent progress from both theoretical and experimental perspectives.Theoretically,the focus is on advances in modeling mode instability and nonlinear effects,aiming to provide optimization guidelines for achieving high-power output.Experimentally,OAIFLs have successfully realized kilowatt-level narrow-linewidth and 10-kW-class broadband laser output in conventional wavelength bands.Beyond these bands,research primarily targets 1 050 nm and 1 018 nm fiber lasers.Furthermore,innovative dual-end output designs address core high-power challenges through distributed power extraction,significantly enhancing system power scalability.These advancements will accelerate broader applications in industrial processing,biomedical fields,and national defense.Analysis of current trends highlights key evolutionary pathways:benefiting from the integrated structure's unique advantages in nonlinear management and amplified spontaneous emission(ASE)suppression,operational wavelengths are expanding from the conventional 1 050-1 080 nm range toward shorter specialty bands;driven by demands in coherent beam combining and high-precision spectroscopy for high-brightness sources,output spectra are shifting from broadband to narrow-linewidth emission;gain media are evolving from conventional homogeneous fibers to specially designed geometric structures to simultaneously mitigate nonlinear effects and transverse mode instability(TMI)under high-power conditions;to meet needs in precision machining,spectroscopic sensing,and scientific research for lasers with high peak power and tailored temporal profiles,operational modes are diversifying from continuous-wave to varied pulsed regimes;and output configurations are advancing from simple single-end to sophisticated dual-end designs,effectively addressing key challenges in high-power laser delivery.Nevertheless,persistent limitations include insufficient universality of theoretical models and a lack of systematic experimental validation.Future research should emphasize two complementary dimensions.Theoretically,efforts must deepen model construction and mechanistic analysis—including refining temporal modeling,investigating TMI origins and nonlinear coupling mechanisms,and elucidating the physics of pump-timing-independent operation.Experimentally,the focus should be on continuously optimizing output performance—enhancing power and efficiency,improving spectral characteristics and beam quality,and advancing toward pulsed and supercontinuum generation capabilities.
段梦;孟祥明;吴函烁;叶云;王鹏;张汉伟;王小林
国防科技大学 前沿交叉学科学院,长沙 410073国防科技大学 前沿交叉学科学院,长沙 410073国防科技大学 前沿交叉学科学院,长沙 410073||国防科技大学 南湖之光实验室,长沙 410073||国防科技大学 高能激光技术湖南省重点实验室,长沙 410073国防科技大学 前沿交叉学科学院,长沙 410073||国防科技大学 南湖之光实验室,长沙 410073||国防科技大学 高能激光技术湖南省重点实验室,长沙 410073国防科技大学 前沿交叉学科学院,长沙 410073||国防科技大学 南湖之光实验室,长沙 410073||国防科技大学 高能激光技术湖南省重点实验室,长沙 410073国防科技大学 前沿交叉学科学院,长沙 410073||国防科技大学 南湖之光实验室,长沙 410073||国防科技大学 高能激光技术湖南省重点实验室,长沙 410073国防科技大学 前沿交叉学科学院,长沙 410073||国防科技大学 南湖之光实验室,长沙 410073||国防科技大学 高能激光技术湖南省重点实验室,长沙 410073
信息技术与安全科学
光纤激光振荡-放大一体化光纤激光器高功率受激拉曼散射模式不稳定
fiber laseroscillating-amplifying integrated fiber laserhigh powerstimulated Raman scatteringmode instability
《强激光与粒子束》 2026 (5)
87-107,21
国家自然科学基金项目(62305390)湖南省杰出青年基金项目(2023JJ10057)国防科技大学自主创新科学基金项目(25-ZZCX-XXXJS-3,ZK24-15)
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