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Recent advances in real-time spectrum measurement of soliton dynamics by dispersive Fourier transformation

Yunzheng Wang, Cong Wang, Feng Zhang, Jia Guo, Chunyang Ma, Weichun Huang, Yufeng Song, Yanqi Ge, Jie Liu, Han Zhang

2020Reports on Progress in Physics61 citationsDOI

Abstract

Mode-locking lasers have not only produced huge economic benefits in industrial fields and scientific research, but also provided an excellent platform to study diverse soliton phenomena. However, the real-time characterization of the ultrafast soliton dynamics remains challenging for traditional electronic instruments due to their relatively low response bandwidth and slow scan rate. Consequently, it is urgent for researchers to directly observe these ultrafast evolution processes, rather than just indirectly understand them from numerical simulations or averaged measurement data. Fortunately, dispersive Fourier transformation (DFT) provides a powerful real-time measurement technique to overcome the speed limitations of traditional electronic measurement devices by mapping the frequency spectrum onto the temporal waveform. In this review, the operation principle of DFT is discussed and the recent progress in characterizing the ultrafast transient soliton dynamics of mode-locking lasers is summarized, including soliton explosions, soliton molecules, noise-like pulses, rogue waves, and mode-locking buildup processes.

Topics & Concepts

PhysicsUltrashort pulseSolitonWaveformFourier transformLaserBandwidth (computing)Mode-lockingOpticsComputational physicsQuantum mechanicsTelecommunicationsNonlinear systemComputer scienceVoltageAdvanced Fiber Laser TechnologiesLaser-Matter Interactions and ApplicationsSolid State Laser Technologies
Recent advances in real-time spectrum measurement of soliton dynamics by dispersive Fourier transformation | Litcius