Hostname: page-component-848d4c4894-x24gv Total loading time: 0 Render date: 2024-05-21T23:13:19.859Z Has data issue: false hasContentIssue false
  • English
  • Français

A Synergistic Approach to Environmental Concerns in Large Scale MOCVD Processes

Published online by Cambridge University Press:  15 February 2011

A. G. Thompson ,
G. S. Tompa ,
P. A. Zawadzki ,
M. Mckee ,
C. Beckham ,
A. Powers ,
A. Gurary ,
K. Moy  and
N. E. Schumaker
A. G. Thompson
Affiliation:
EMCORE Corporation, 35 Elizabeth Avenue, Somerset, NJ 08873.
G. S. Tompa
Affiliation:
EMCORE Corporation, 35 Elizabeth Avenue, Somerset, NJ 08873.
P. A. Zawadzki
Affiliation:
EMCORE Corporation, 35 Elizabeth Avenue, Somerset, NJ 08873.
M. Mckee
Affiliation:
EMCORE Corporation, 35 Elizabeth Avenue, Somerset, NJ 08873.
C. Beckham
Affiliation:
EMCORE Corporation, 35 Elizabeth Avenue, Somerset, NJ 08873.
A. Powers
Affiliation:
EMCORE Corporation, 35 Elizabeth Avenue, Somerset, NJ 08873.
A. Gurary
Affiliation:
EMCORE Corporation, 35 Elizabeth Avenue, Somerset, NJ 08873.
K. Moy
Affiliation:
EMCORE Corporation, 35 Elizabeth Avenue, Somerset, NJ 08873.
N. E. Schumaker
Affiliation:
EMCORE Corporation, 35 Elizabeth Avenue, Somerset, NJ 08873.
Get access

Abstract

Processes used in the production of epitaxial III-V semiconducting materials employ a wide variety of materials that are environmentally hazardous. As production volumes increase, the need to manage these materials becomes a serious concern. As the leading supplier of production scale single and multi-wafer MOCVD systems, we have taken the approach of minimizing the generation of waste by designing our reactor for high reactant utilization efficiency, and then trapping the remainder so that the exhaust stream is clean. We have paid particular attention to both operational efficiency and operator safety. The traps may be simply removed and replaced, with cleaning being performed off line. The trapped materials are reduced to an inert state for subsequent commercial disposal; this is particularly important for phosphorus, which can be highly flammable if improperly handled. The reactor chamber deposits occur below the wafer level and typically are cleaned only after several hundred deposition cycles. These factors contribute to a quick cycle time and high uptime, both of which increase throughput. These issues become more important as the reactor size is increased and when multiple shifts are utilized. These points are exemplified by our operational experience with our new Enterprise series, which holds four 100mm wafers (or seventeen 50mm wafers) per run. We will discuss the progressive trapping of solid As and P compounds and those hydride gases which are not completely decomposed in the reaction chamber. The use of computer modeling to scale the process to larger dimensions and to optimize the deposition conditions will also be discussed.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 344: Symposium I – Materials and Processes for Environmental Protection , 1994 , 223
Copyright
Copyright © Materials Research Society 1994

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. Stringfellow, G.B., Organometallic Vapor-Phase Epitaxy, (Academic Press, San Diego, 1989)Google Scholar
2. Shastry, S.S. and Hill, D.S., Microelectronics Manufacturing Technology, April 1991, 49Google Scholar
3. Tompa, G.S., McKee, M.A., Beckham, C., Zawadski, P.A., Colabella, J.M., Reinert, P.D., Capuder, K., Stall, R.A. and Norris, P.E., J.Crystal Growth 93, 220 (1988)Google Scholar
4. Schumaker, N.E., Stall, R.A., Wagner, W.R. and Polgar, L.G., J. of Metals, June 1986, 41Google Scholar
5. Evans, G.H. and Greif, R., Sandia Report SAND86-8843, July 1986 Google Scholar
6. Breiland, W.G. and Evans, G.H., J.Electrochem.Soc. 138, 1806 (1991)Google Scholar
7. Fotiadis, D.I., Kieda, S. and Jensen, K.F., J.Crystal Growth 102, 441 (1990)Google Scholar
8. Biber, C.R., Wang, C.A. and Motakef, S., J.Crystal Growth 123, 545 (1992)Google Scholar
9. Davis, R.W., Moore, E.F. and Zachariah, M.R., J.Crystal Growth 132, 513 (1993)Google Scholar
10. Colabella, J.M., Stall, R.A. and Sorenson, C.T., J.Crystal Growth 92, 189 (1988)Google Scholar
11. Hardwick, S.J., McManus, J.V. and Scaringella, J.C., presented at the 6th Biennial Workshop on Organometallic Vapor Phase Epitaxy, Palm Springs, CA, 1993 (unpublished)Google Scholar
12. Burggraaf, P., Semiconductor International, April 1993, 44Google Scholar
13. Lum, R.M., Klingert, J.K. and Lamont, M.G., J.Crystal Growth 89, 137 (1988)Google Scholar
14. Stringfellow, G.B., J.Electronic Materials 17, 327 (1988)Google Scholar
15. Jones, A.C., J.Crystal Growth 129, 728 (1993)Google Scholar
16. Li, S., Tompa, G.S., Moy, K., West, S.B., Nelson, C.R., Stall, R.A., Burnham, R. and Smith, S., J.Electronic Materials 21, 149 (1992)Google Scholar