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Growth of Oriented Thick Films of Gallium Nitride From the Melt

Published online by Cambridge University Press:  15 February 2011

Jeffrey S. Dyck ,
Kathleen Kash ,
Michael T. Grossner ,
Cliff C. Hayman ,
Alberto Argoitia ,
Nan Yang ,
Moon-Hi Hong ,
Martin E. Kordesch  and
John C. Angus
Jeffrey S. Dyck
Affiliation:
Dept of Physics, [email protected]
Kathleen Kash
Affiliation:
Dept of Physics, [email protected]
Michael T. Grossner
Affiliation:
Dept of Chemical Engineering
Cliff C. Hayman
Affiliation:
Dept of Chemical Engineering
Alberto Argoitia
Affiliation:
Dept of Chemical Engineering
Nan Yang
Affiliation:
Dept of Materials Science and Engineering Case Western Reserve University, Cleveland, OH 44106
Moon-Hi Hong
Affiliation:
Dept of Materials Science and Engineering Case Western Reserve University, Cleveland, OH 44106
Martin E. Kordesch
Affiliation:
Dept of Physics and Astronomy, Ohio University, Athens, OH 45701
John C. Angus
Affiliation:
Dept of Chemical Engineering
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Abstract

While significant strides have been made in the optimization of GaN-based devices on foreign substrates, a more attractive alternative would be homoepitaxy on GaN substrates. The primary motivation of this work is to explore the growth of thick films of GaN from the melt for the ultimate use as substrate material. We have previously demonstrated the synthesis of polycrystalline, wurtzitic gallium nitride and indium nitride by saturating gallium metal and indium metal with atomic nitrogen from a microwave plasma source. Plasma synthesis avoids the high equilibrium pressures required when molecular nitrogen is used as the nitrogen source. Here we report the growth of thick oriented GaN layers using the same technique by the introduction of (0001) sapphire into the melt to serve as a substrate. The mechanism of this growth is not established, but may involve transport of the metal as a liquid film onto the sapphire and subsequent reaction with atomic nitrogen. The films were characterized by x-ray diffraction, scanning electron microscopy, transmission electron microscopy, and Raman spectroscopy. X-ray diffraction showed that the GaN films were oriented with their c-axes parallel to the sapphire c-axis. The TEM analysis confirmed the orientation and revealed a dislocation density of approximately 1010 cm-2. The E2 Raman active phonon modes were observed in the GaN films.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 537: Symposium G – GaN and Related Alloys , 1998 , G3.23
Copyright
Copyright © Materials Research Society 1999

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References

1. Nam, O.H., Bremser, M.D., Zheleva, T.S., and Davis, R.F., Appl. Phys. Lett. 71, 2638 (1997).Google Scholar
2. Sakai, A., Sunakawa, H., and Usui, A., Appl. Phys. Lett. 71, 2259 (1997).Google Scholar
3. Porowski, S. and Grzegory, I., J. Cryst. Growth 178, 174 (1997).Google Scholar
4. Krukowski, S., Romanowski, Z., Grzegory, I., and Porowski, S., in III-V Nitride Materials and Processes II, edited by Abernathy, C.R., Brown, W.D., Buckley, D.N., Dimsukes, J.P., Kamp, M., Moustakas, T.D., Pearton, S.J. and Ren, F. (Electrochemical Society Symp. Proc. 97–34, Paris, 1997) pp. 189200 Google Scholar
5. Kim, S.T., Lee, Y.J., Moon, D.C., Hong, C.H., and Yoo, T.K., J. Cryst. Growth 194, 37 (1998).Google Scholar
6. Molnar, R.J., Gotz, W., Romano, L.T., and Johnson, N.M., J. Cryst. Growth 178, 147 (1997).Google Scholar
7. Argoitia, A., Hayman, C.C., Angus, J.C., Wang, L., Dyck, J.S., and Kash, K., Appl. Phys. Lett. 70, 179 (1997).Google Scholar
8. Angus, J.C., Hayman, C.C., Evans, E.A., and Argoitia, A., Proc. III-V Nitride Materials and Processes II, edited by Abernathy, C.R., Brown, W.D., Buckley, D.N., Dismukes, J.P. Kamp, M., Moustakas, T.D., Pearton, S.J., and Ren, F., (Electrochem. Soc. Symp. Proc. 97–34, Pennington, NJ, 1997) pp. 201208.Google Scholar
9. Angus, J.C., Argoitia, A., Hayman, C.C., Wang, L., Dyck, J.S., and Kash, K. in Gallium Nitride and Related Materials II, edited by Abernathy, C.R., Amano, H., and Zolper, J.C. (Mater. Res. Soc. Symp. Proc. 468, Pittsburgh, PA, 1997) pp. 149154.Google Scholar
10. Dyck, J.S., Kash, K., Kim, K., Lambrecht, W.R.L., Hayman, C.H., Argoitia, A., Grossner, M.T., Zhou, W., and Angus, J.C. in Nitride Semiconductors, edited by Ponce, F.A, DenBaars, S.P., Meyer, B.K., Nakamura, S., and Strite, S. (Mat. Res. Soc. Symp. Proc. Vol. 482, Pittsburgh, PA, 1998) pp. 549554.Google Scholar
11. Dyck, J.S., Kash, K., Hayman, C.C., Argoitia, A., Grossner, M.T., Angus, J.C., and Zhou, W., J. Mat. Res. (accepted for publication) 1998.Google Scholar
12. Logan, R.A. and Thurmond, C.D., J. Electrochem. Soc. 119, 1727 (1972).Google Scholar
13. Madar, R., Jacob, G., Hallais, J., and Fruchart, R., J. Cryst. Growth 31, 197 (1975).Google Scholar
14. Elwell, D., Feigelson, R.S., Simkins, M.M., and Tiller, W.A., J. Cryst. Growth 66, 45 (1984).Google Scholar
15. Toy, C. and Scott, W.D., J. Mat. Sci. 32, 3243 (1997).Google Scholar