Abstract
A quasi-3D simulation for quantum well (QW) distributed feedback (DFB) laser diodes is presented. It takes into account both longitudinal effects such as the nonuniformity of the optical intensity, local gain, and spontaneous emission, and lateral effects such as current spreading, quantum carrier capture, and quantum carrier heating. The simulation is performed by solving several 2D cross-sections using Minilase II and a 1D longitudinal solver in a self-consistent fashion. As an example, an analysis of spatial hole burning in a λ/4 phase shifted DFB laser is given. It is shown that spatial hole burning (SHB) results in a local gain saturation, and is mainly restricted to electrons and holes within the QW. Investigations of electron heating at high power show that the temperature distribution of the bound electrons and the LO phonons in the QW is insignificant, and only slightly influenced by SHB.
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