Abstract :
The optical properties and recombination kinetics of the InGaN/GaN double quantum well (DQW) structures with different well thickness (Lw) have been studied by means of photoluminescence (PL), time-resolved PL, and cathodoluminescence (CL) measurements. With increasing quantum well thickness up to 4 nm, the PL emission energy decreases and the blueshift of the PL emission energy increases with increasing excitation density. On the other hand, the PL emission energy of the DQWs with Lw=16 nm is higher than that of the DQWs with Lw=4 nm, and is independent of the excitation density. With increasing Lw from 1 to 4 nm, the PL decay times increase. In contrast, the decay times of 16 nm DQWs are faster than those of 4 nm DQWs. These different results for 16 nm DQWs such as the blueshift of the emission energy, the decrease of the excitation density dependence, and the increase of recombination rate can be ascribed to the relaxation of the piezoelectric field. We also observed the inhomegeneity in the CL spectra of the DQWs with Lw=1 nm on 1 μm scale.
