Title :
Simulations of boundary layers and point defects in coupled VCSEL arrays
Abstract :
The inherent gain dependence on carrier depletion and on the lateral cavity interactions differentiates active photonic lattices from passively coupled models, employing a given complex gain profile. This paper addresses coupled vertical-cavity surface-emitting laser array effects due to finite boundaries and the possibility of individual bias failures, of interest for practical applications. The "cold-cavity" characteristic parameters are assumed identical, focusing on biasing defects and site vacancies. Analysis and numerical simulations based on the tight-binding approximation show that phase-locking persists in finite arrays. Self-regulation of the edge cavity density and power generate boundary layers of differentiated cavity operation values. The inter-cavity phase shift remains nearly uniform, with a small superimposed linear slope caused by cross-cavity reflection interference from distributed Bragg reflectors. Phase locking is robust against partial or complete failure to lase for individual cavity sites, or even entire rows, due to biasing errors.
Keywords :
boundary layers; distributed Bragg reflector lasers; laser cavity resonators; laser mode locking; light interference; light reflection; semiconductor device models; semiconductor laser arrays; surface emitting lasers; tight-binding calculations; vacancies (crystal); active photonic lattices; bias failures; biasing defects; biasing errors; boundary layer simulation; carrier depletion; cavity sites; cold-cavity characteristic parameters; complex gain profile; coupled VCSEL arrays; coupled vertical-cavity surface-emitting laser array; cross-cavity reflection interference; differentiated cavity operation; distributed Bragg reflectors; edge cavity density self-regulation; finite arrays; finite boundaries; inherent gain dependence; intercavity phase shift; lateral cavity interactions; passively coupled models; phase-locking; point defects; site vacancies; superimposed linear slope; tight-binding approximation; Laser modes; Lattices; Numerical simulation; Optical arrays; Optical coupling; Optical reflection; Phased arrays; Power generation; Surface emitting lasers; Vertical cavity surface emitting lasers; Boundary layers; coupled cavities; defects; phased arrays;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2005.853782
