Native oxide and hydroxides and their implications for bulk AlN crystal growth

Oxygen degrades the properties of AlN, thus producing bulk single crystals with low oxygen concentrations is an important goal. Most of the oxygen in bulk AlN single crystals grown by the sublimation–recondensation method originates from the hydroxides and oxides that spontaneously form on the surfa...

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Bibliographic Details
Published in:Journal of crystal growth 2008-08, Vol.310 (17), p.4002-4006
Main Authors: Edgar, J.H., Du, L., Nyakiti, L., Chaudhuri, J.
Format: Article
Language:English
Subjects:
A1. Impurities
A1. Purification
A2. Growth from vapors
B1. Nitrides
B2. Semiconducting aluminum compounds
Cross-disciplinary physics: materials science
rheology
Exact sciences and technology
Growth from vapor
Materials science
Methods of crystal growth
physics of crystal growth
Physics
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Summary:Oxygen degrades the properties of AlN, thus producing bulk single crystals with low oxygen concentrations is an important goal. Most of the oxygen in bulk AlN single crystals grown by the sublimation–recondensation method originates from the hydroxides and oxides that spontaneously form on the surfaces of the AlN source powder. For a typical AlN powder with an average particle size of 1–2 μm, a 1–3 nm thick oxide and/or hydroxide can account for most of its oxygen (generally in the order of 1.0 wt%) and hydrogen (200–300 ppm). Heating the AlN powder source at 1950 °C for 10 h in a nitrogen atmosphere reduced its surface area by a factor of 160 (due to sintering), the oxygen concentration by 16 and the hydrogen concentration by 67. The difference in these reduction factors suggests some of the oxygen is dissolved into the bulk AlN with this heat treatment. Firstly annealing the AlN powder at a low temperature (950–1000 °C) for several hours before sintering at 1950 °C, the oxygen and hydrogen concentrations were reduced to lower levels. The low-temperature treatment is effective in eliminating oxygen and hydrogen from the surface of the powder, while high-temperature sintering reduces the specific surface area of the source. The combination of heat treatments produced a source with oxygen and hydrogen concentrations as low as 0.015 wt% O (1.9×10 19 atoms O cm −3) and 1.7 ppm H (3.4×10 18 atoms H cm −3). Annealing becomes less effective at removing oxygen and hydrogen with longer heat treatments, suggesting there is a minimum oxygen concentration that can be produced by this method.
ISSN:0022-0248
1873-5002
DOI:10.1016/j.jcrysgro.2008.06.014