Gain and internal losses in InGaAsSb/InAsSbP double-heterostructure lasers

Abstract

We report on a study characterizing internal losses and the gain in InGaAsSb/InAsSbP diode-heterostructure lasers emitting in the mid-infrared (3–4 µm). Numerical simulations of the current dependence of the intensity of spontaneous emission above the laser threshold and of the differential quantum efficiency allowed us to determine the intraband absorption k0 ≈5.6×10−16 cm2. The cavity-length dependence of the threshold current is used to estimate the internal losses at zero injection current α0≈5 cm−1. Calculations of the internal losses at laser threshold showed that they increase more than fourfold when the cavity length is decreased from 500 µm to 100 µm. The temperature dependence of the differential quantum efficiency is explained on the assumption that intraband absorption with hole transitions into a split-off band occurs. It is shown that the maximum operating temperature of “short-cavity” lasers is determined by the intraband absorption rather than by Auger recombination. The internal losses are shown to have a linear current dependence. The separation of the quasi-Fermi levels as a function of current demonstrates an absence of voltage saturation of the p-n junction above threshold.