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Dispersive Instabilities in Passively Mode-Locked Integrated External-Cavity Surface-Emitting Lasers

Christian Schelte, Denis Hessel, Julien Javaloyes, Svetlana V. Gurevich

2020Physical Review Applied25 citationsDOIOpen Access PDF

Abstract

We analyze the dynamics of passively mode-locked integrated external-cavity surface-emitting lasers (MIXSELs) using a first-principles dynamical model based on delay algebraic equations. We show that the third-order dispersion stemming from the lasing microcavity induces a train of decaying satellites on the leading edge of the pulse. Due to the nonlinear interaction with carriers, these satellites may get amplified, thereby destabilizing the mode-locked states. In the long-cavity regime, the localized structures that exist below the lasing threshold are found to be deeply affected by this instability. As it originates from a global bifurcation of the saddle-node infinite-period type, we explain why the pulses exhibit forms of behavior characteristic of excitable systems. Using the multiple-time-scale and the functional-mapping methods, we derive rigorously a master equation for MIXSELs in which third-order dispersion is an essential ingredient. We compare the bifurcation diagrams of the two models and assess their good agreement.

Topics & Concepts

Lasing thresholdBifurcationPhysicsDispersion (optics)Nonlinear systemLaserSemiconductor laser theoryEnhanced Data Rates for GSM EvolutionAlgebraic numberLeading edgeDynamics (music)Statistical physicsBifurcation diagramOpticsRadiationBifurcation theoryAlgebraic equationBiological applications of bifurcation theoryClassical mechanicsDispersion relationComputational physicsNonlinear Dynamics and Pattern FormationSemiconductor Lasers and Optical DevicesNeural Networks and Reservoir Computing