Quantum-dot laser diodes represent the most promising alternative to heterogeneous III-V/Si light sources toward an all-epitaxial integration of future optical transmission systems based on silicon photonics. The major limiting factor to this approach is represented by the high density of dislocations found within the III-V active layers as a consequence of the heteroepitaxy, which lowers both the performance and the long-term reliability of the laser sources. This latter point has already been investigated in literature by means of statistical analyses, which identified a cubic dependence of the lifetime of the optical source on the density on dislocations. The goal of this paper, on the other hand, is to investigate from a physical point of view the defects-related degradation processes that affect this family of IR optical sources.

This paper investigates the impact of dislocation density and active layer structure on the degradation mechanisms of 1.3 μm InAs Quantum Dot (QD) lasers for silicon photonics. We analyzed the optical behavior of two sets of samples, having different dislocation densities and different number of quantum dot layers in the active region. The samples were subjected to a short-term step-stress experiment and to long-term constant current operation in order to investigate the dominant degradation processes. The results indicate that: (i) the temperature stability is much higher in the devices grown on native substrate, thanks to the lower defect density; (ii) the roll-off current is considerably higher for the devices with higher number of layers, due to the lower density of carriers in the QDs; (iii) in nominal ground-state operating regime, the degradation rate is limited by the density of dislocations, that may serve as preferential paths for the diffusion of non-radiative recombination ...