Time-Stretch Probing of Ultrafast Soliton Molecule Dynamics

TL;DR

This paper employs the time stretch technique to observe real-time ultrafast soliton molecule dynamics in a femtosecond fiber laser, revealing formation, vibrations, collisions, and decay processes that were previously difficult to capture.

Contribution

It introduces a novel application of the time stretch method to directly visualize transient soliton molecule behaviors in real time.

Findings

Real-time observation of soliton molecule formation and breakup

Identification of diverse soliton dynamics including vibrations and collisions

Detection of non-stationary mode-locking regimes with transient solitons

Abstract

Soliton molecules are the manifestation of attractive and repulsive interaction between optical pulses mediated by a nonlinear medium. However, the formation and breakup of soliton molecules are difficult to observe due to the transient nature of the process. Using the time stretch technique, we have been able to track the real-time evolution of the bound state formation in a femtosecond fiber laser and unveil different evolution paths towards a stable bound state. A non-stationary Q-switched mode-locking regime consisting of various transient solitons is observed in this transition period. We also observe additional dynamics including soliton molecule vibrations, collision and decay. Our findings uncover a diverse set of soliton dynamics in an optical nonlinear system and provide valuable data for further theoretical studies.