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Chemical ordering in AlGaN layers grown by MOCVD

Published online by Cambridge University Press:  17 March 2011

P. Ruterana  and
F. Omnes
P. Ruterana*
Affiliation:
ESCTM-CRISMAT, Institut des Sciences de la Matiére et du Rayonnement, 6 Bd Maréchal Juin, 14050 Caen, France
F. Omnes
Affiliation:
Centre de Recherche sur l' Hétéroépitaxie et ses Applications (CRHEA - CNRS), rue Bernard Gregory Sophia-Antipolis, 06560Valbonne, France
*
Corresponding author: tel +33 2 31 45 26 53, fax +33 2 31 45 26 60, email ruterana@lermat8.ismra.fr
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Abstract

One of the applications of wurtzite gallium based nitride compounds will be to provide optoelectronic devices from 6.2eV (AlN) to 1.89eV (InN). This will depend on the possibility to grow wurtzite AlGaN and InGaN ternary alloys. As expected, the most difficult region is InGaN due to the large misfit between GaN and InN (= 10%), in this case, ordering, phase separation and growth instabilities have been reported. In the case of AlN and GaN, the misfit is smaller (∼ 2.5%) and one would expect more stable growth. However, it was in this system that ordering along the c axis between AlN and GaN was reported for the first time.

In this work, we have found that the growth of AlGaN may be more complicated. Not only the wurtzite lattice can be decreased to simple hexagonal by AlN/GaN ordering along the c axis, but the growth can lead to other types of stackings. Even in the low Al composition range, 10 - 15%, we have found that three processes can operate:

1. Ordering into AlN/GaN as two simple hexagonal sublattices.

2. The 3:1 ordering which has been recently reported to occur in InGaN.

3. A new type of ordering where diffraction experiments (XR and electron diffraction) detect superlattice reflection with a period close to 3 nm. The most adequate model which was found to take this into account shows that, in these growth conditions, the system has preferred to form one AlN cell in between 5 GaN cells, leading to a 5:1 ordering.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 639: Symposium G – GaN and Related Alloys-2000 , 2000 , G3.10
Copyright
Copyright © Materials Research Society 2001

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References

REFERENCES

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