Spatially indirect interfacial excitons in n+-ZnO/p-GaN heterostructures

Abstract

Electroluminescence properties of epitaxially grown n+-ZnO/p-GaN pn+-heterojunctions are investigated as functions of applied bias and temperature. This study reveals the existence of indirect interfacial excitons at sufficiently low temperatures. Electroluminescence feature associated with these excitons redshifts with increasing forward bias. It has been found that the binding energy of these entities can be controlled through applied forward bias and can even be made higher than that of the excitons in ZnO bulk (60 meV). However, the formation of these excitons becomes unsustainable when either the applied bias or the temperature crosses a threshold. This has been explained in terms of leakage and thermal escape of electrons (holes) into the GaN (ZnO) side. Calculations for the band diagram and the binding energy of these spatially indirect electron–hole coulomb-coupled entities are carried out. Theoretical results are found to explain the experimental findings quite well.