Title :
A coupled-mode model for the Fabry-Perot semiconductor laser kink instability
Author :
White, J.K. ; Moloney, J.V.
Author_Institution :
Bookham Technol., Nepean, Ont., Canada
Abstract :
This paper derives a coupled-mode Fabry-Perot semiconductor laser model from the longitudinal-mode laser rate equations with parabolic gain dispersion. Truncating the full coupled-mode model permits stability analysis of the Fabry-Perot laser kink instability, which is a mode hop with increasing current. Two mechanisms contribute to the mode hop: the Silberberg-Bar-Joseph instability transports energy from higher frequencies to lower frequencies and gain dispersion stops the energy transport. Numerical simulations have shown that higher order carrier modes are excited during intervals of energy transport among the optical modes. These numerical results suggest that modes greatly detuned from the peak gain affect the laser dynamics.
Keywords :
Fabry-Perot resonators; Kramers-Kronig relations; coupled mode analysis; differential equations; eigenvalues and eigenfunctions; laser cavity resonators; laser stability; optical susceptibility; semiconductor device models; semiconductor lasers; wave equations; Fabry-Perot semiconductor laser; Kramers-Kronig transformation; Silberberg-Bar-Joseph instability; counter-propagating wave equations; coupled ordinary differential equations; coupled-mode model; higher order carrier modes; laser cavity modes; laser kink instability; longitudinal-mode laser rate equations; mode hop; optical susceptibility; parabolic gain dispersion; self-consistent parabolic gain dispersion; semiconductor device modeling; Equations; Fabry-Perot; Frequency; Laser excitation; Laser modes; Laser stability; Numerical simulation; Optical coupling; Semiconductor lasers; Stability analysis;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2003.819409
