Abstract We have measured the spatial dependence of photoluminescence in thin films of Cu-poor Cu(In,Ga)Se 2 with submicrometer resolution. We found large variations in the photoluminescence signal by more than a factor of 5 confined to domains much larger than the typical grain size of 1 μm in the films. Numerical simulation of the diffusion and recombination of photoexcited carriers shows that grain boundary recombination velocities of 10 6 cm/s may lead to approximately 40% variation in the photoluminescence signal. The large differences in photoluminescence efficiency are interpreted in terms of different material phases or defect structures in the off-stoichiometric quaternary chalcopyrite system. From the variation of the photoluminescence intensity at 70 K, we deduced a maximum lateral variation in the quasi-Fermi level splitting of 10 meV.
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