GaN and GaInN quantum dots: an efficient way to get luminescence in the visible spectrum range

It is shown that both GaN and Ga0.8In0.2N quantum dots QDs.can be grown by molecular beam epitaxy on silicon or sapphire substrates making use of the strain-induced two-dimensional 2D.–three dimensional 3D.growth mode occurring for mismatched materials Stranski–Krastanov, SK, mode of growth.. GaN and Ga0.8In0.2N QDs were embedded in an AlN and a GaN matrix, respectively. Despite the dislocation density which can exceed 1010 cmy2 on silicon substrate., strong visible room temperature photoluminescence PL.is observed owing to the QD related carrier localization and to the high QD density. Although GaN and AlN have band-gaps yielding to ultra-violet emission, the PL related to the GaN QDs is in the visible part of the electromagnetic spectrum. This is due to the presence of a large built-in electric field, which induces a strong quantum-confined Stark effect, and thereby an important red shift of the PL. It is demonstrated that the emission wavelength can be tuned in almost the whole visible spectrum range by simply varying the GaN or the GaInN QD size. The luminescence efficiency is found to be significantly larger in QD structures than in standard quantum well QW.structures. q2000 Elsevier Science B.V. All rights reserved.