AlON: A brief history of its emergence and evolution

In the early 1970s in Japan, the United States and France it was found that additions of nitrogen into aluminum oxide resulted in new spinel-like phases. At about the same time there was much increased interest in oxynitrides, stimulated by Professor K. Jack in the UK and Y. Oyama in Japan. Followin...

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Bibliographic Details
Published in:Journal of the European Ceramic Society 2009, Vol.29 (2), p.223-236
Main Authors: McCauley, James W., Patel, Parimal, Chen, Mingwei, Gilde, Gary, Strassburger, Elmar, Paliwal, Bhasker, Ramesh, K.T., Dandekar, Dattatraya P.
Format: Article
Language:English
Subjects:
AlON
History
Phase equilibrium
Processing
Properties
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Summary:In the early 1970s in Japan, the United States and France it was found that additions of nitrogen into aluminum oxide resulted in new spinel-like phases. At about the same time there was much increased interest in oxynitrides, stimulated by Professor K. Jack in the UK and Y. Oyama in Japan. Following these activities a major research program in this area was initiated at the Army Materials and Mechanics Research Center in Watertown, Massachusetts in 1974. These efforts resulted in the first complete Al 2O 3–AlN phase equilibrium diagram and a process to reactively sinter to nearly full density, translucent aluminum oxynitride spinel ceramic, which was named AlON. Subsequently, the Raytheon Company further developed AlON into a highly transparent material (ALON™) with many applications including transparent armor and EM domes and windows, among others—the technology was recently transferred to the Surmet Corporation. This paper will review the early history, phase equilibrium, crystal chemistry, and properties of this material, along with more recent work in our laboratory on transient liquid phase sintering and new data on lattice parameter measurements. In addition, recent results of collaborative work on AlON's dynamic mechanical properties using plate impact, Kolsky bar and edge-on impact (EoI) experimental techniques, including preliminary modeling at the microstructural scale of AlON in the EoI test, will be presented.
ISSN:0955-2219
1873-619X
DOI:10.1016/j.jeurceramsoc.2008.03.046