Effect of free carriers and excitons on the gain and temperature characteristics of InAs/InGaAs quantum dot lasers

In this work we study the role of free carriers and excitons on the characteristics of 1.3 mum InAs/InGaAs quantum dot lasers. The study is carried out theoretically by building a mathematical model to calculate the threshold current in the laser and the characteristic temperature, T-0. In order to determine the role of free carrier and excitons on the laser characteristics the model allows for different carrier distribution assumptions to be used, and we look at three cases; all free carriers, all excitons, and both free carriers and excitons in the dots. Our model results show that if we allow either free carriers or excitons to exist but not both, the calculated threshold current and T-0 do not match with the experimental values. Thus we conclude that both free and bound carriers must exist and develop a method for modeling this case. We use a modified form of the Saha equation to calculate the ratio of free carriers to excitons and modify the material gain to account for this ratio. This model results in a threshold current density of similar to39A/cm(2) and a T-0 of 83K, both of which are in excellent agreement with experimental results.