Figure 6 shows the evolution of the two Gaussian fitting curves a

Figure 6 shows the evolution of the two Gaussian fitting curves as function of P in. At low incident power, the separation between their peak energies ΔE keeps constant, together with the ratio of their amplitude I

D/I L; this indicates that carriers are well localized, and delocalized excitons play a minor role. With increasing P in, excitons begin to delocalize and dominate in amplitude I D, and the hot carrier population fills the density of selleck inhibitor states moving the two Gaussians apart. The FWHM, plotted in the inset of Figure 6, shows that the localized contribution has a flatter broadening over power compared to the delocalized excitons, but both Gaussians are always present and mixed all along the investigated power range. We are indeed aware that the exciton delocalization,

even at higher P in, is not complete but dominates over the localized contribution. selleck chemical This result confirms the strong exciton localization and alloy inhomogeneity present in GaAsBi alloys [17, 18]. Figure 6 Evolution of the two Gaussian fitting curves vs. P in , in terms of ΔE separation and intensity ratio. The inset shows the P in dependence of the fits’ FWHM. Another way to distinguish the localized and delocalized excitons is to check their time evolution after laser pulse excitation. An example of the power dependence of the time-resolved photoluminescence (TRPL) curve sampled at the PL peak is shown in Figure 7. While at low P in, Teicoplanin the carriers are frozen in the localized states (extremely long decay time); at the highest P see more in, the PL decay times become shorter, confirming the saturation of these states and the increase

of the oscillator strength involved in the delocalized exciton recombination. Figure 7 Power dependence of the TRPL curve measured at the PL peak for sample 5. Curves are shifted for clarity. Again, the different exciton contributions can be spectrally separated, and this is evident when showing the streak camera image, together with the acquisition energy dependence of the PL decay curve taken at fixed excitation power, as represented in Figure 8. In Figure 8a, the GaAs TRPL transition is also visible above 1.5 eV and shows the fast decay time caused by the high defect density in the non-optimal grown LT-GaAs layer [15]. In Figure 8b, the GaAsBi PL decay is reported for different detection energies. As expected, the PL decay time increases when the detection energy decreases, due to carrier thermalization toward localized states, which are characterized by lower oscillator strength and hence longer recombination times. This observation is in good agreement with previously reported results on a similar GaAsBi sample [18]. For what concerns the GaAsBi transition, as expected, the population of hot carriers is established in the higher energy area, and correspondingly, the PL signal decays on a short time scale.

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