IEEE study reveal the physics of laser emission from Mamyshev oscillator

The Mamyshev oscillator (MO) is a type of fiber laser capable of producing high-energy laser pulses at a tunable repetition rate. It is a mode-locked laser which uses light travelling within a closed-loop cavity to produce laser emission. Harmonic mode-locking (HML) is an  advanced form of mode-locking process where multiple laser pulses are produced within one round trip of light. MOs employing HML are used for several advanced applications such as optical communication, frequency metrology, and micromachining.

Despite increasing applications of HML MOs, understanding the light buildup dynamics of HML within these lasers is experimentally challenging. In a recent study  published in Journal of Lightwave Technology, researchers from Hunan University, China have uncovered the buildup dynamics of HML in an all-fiberized erbium-doped MO. They successfully obtained HML pulse outputs of different orders. In these results, the signal-to-noise ratio of all harmonic pulse trains from the all-fiber MO exceeded 80 dB, demonstrating the high stability of the output. Moreover, they investigated the transient dynamics during the startup process of HML in the MO.

“The starting dynamics of HML in the MO, characterized by the time-stretch dispersive Fourier transform technique (TS-DFT) revealed that the generation of HML is not dominated by the splitting effect of the single pulse but the amplification of the multiple seeding pulses in the oscillator”, explains author Dr. Ning Li.

Using carefully designed experiments, the researchers identified five distinct ultrafast phases that occur between the injection of seed pulses into the laser cavity and the stable emission of HML pulses from the MO. These phases include relaxation oscillation, multi-pulses operation, pulse collapse reconstruction, unstable HML, and a stable HML state. Notably, the identified process of stable HML generation was different from the conventional pulse splitting effect thought to result in laser emission dynamics in MOs. The   experimental findings were further supported using numerical simulations.

Using the TS-DFT technique, they monitored the spectra evolution within the MO cavity in real-time and performed a detailed analysis of the dynamic process during HML initiation. Observations revealed that the generation of HML in the MO was not dominated by the conventional single pulse splitting effect but rather by the amplification of multiple seeding pulses within the oscillator.

“Our experimental and simulation results showed that under these conditions, the initial seed pulses within the cavity evolve into stable independent pulses through processes such as gain amplification and energy redistribution, eventually leading to a stable HML state within the resonator”, observes Dr. Li. “Results from our study can deepen the understanding of  HML operation in MOs, and may provide an active way to control the transient pulse dynamics in the high-performance ultrafast laser systems”,  he adds.

Overall, this study has extended our understanding of light buildup dynamics in MOs, specifically for advanced lasers using HML. Furthermore, the study challenges the conventional understanding of the light buildup and emission process in MOs.

Besides clarifying the underlying physics, the insights offered by the study may lead to improved designs of MOs – advancing their use across several fields.

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Reference
Authors: Ning Li et al.

DOI: 10.1109/JLT.2025.3570159

Affiliations: Key Laboratory for Micro-/Nano- Optoelectronic Devices of Ministry of Education, School of Physics and Electronics, Hunan University, Changsha, China

School of Physics and Optoelectronics, Xiangtan University, Xiangtan, China