Dynamics of soliton explosions in a polarization-multiplexed ultrafast fiber laser

•Soliton explosions induced by vector dissipative soliton collisions are observed in a polarization-multiplexed mode-locked fiber laser for the first time.•The spectral and temporal characteristics of the soliton explosions are identified.•Numerical simulations confirm the experimental observations...

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Bibliographic Details
Published in:Results in physics 2023-06, Vol.49, p.106503, Article 106503
Main Authors: Li, Junwen, Li, Heping, Wang, Zhuang, Zhang, Zhiyao, Zhang, Shangjian, Liu, Yong
Format: Article
Language:English
Subjects:
Polarization-multiplexed mode-locked fiber laser
Soliton collisions
Soliton explosions
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Summary:•Soliton explosions induced by vector dissipative soliton collisions are observed in a polarization-multiplexed mode-locked fiber laser for the first time.•The spectral and temporal characteristics of the soliton explosions are identified.•Numerical simulations confirm the experimental observations and reveal the mechanism for soliton explosions. Soliton explosions are among the most striking soliton phenomena in nonlinear dissipative systems. In this regime, quasi-stable solitons suffer abrupt structural collapses and then recover to their original state. Here, we report on the first experimental observation of soliton explosions triggered by vector dissipative soliton collisions in a polarization-multiplexed ultrafast fiber laser. The fiber laser simultaneously generates two orthogonally polarized pulse trains with different repetition rates, which enables periodic soliton collisions in the cavity. Based on the dispersive Fourier transform technique, the spectral dynamics of collision-induced soliton explosions are identified in real time. The corresponding time-domain measurements demonstrate opposite temporal shifts in the two output pulse trains. Numerical simulations validate the experimental observations and give more insights into the physical mechanism for soliton explosions. Our findings can shed new light on the dynamics of soliton explosions.
ISSN:2211-3797
2211-3797
DOI:10.1016/j.rinp.2023.106503