Autor: |
Kadri Vural, R. G. Benz, Lester J. Kozlowski, A. Parikh, James R. Waterman, Scott M. Johnson, C. A. Cockrum, Art Simmons, J. D. Benson, M. J. Bevan, Owen K. Wu, K. A. Harris, Rajesh D. Rajavel, Christopher J. Summers, Jose M. Arias, G. M. Venzor, Steven R. Jost, John E. Jensen, Majid Zandian, H.-D. Shih, J. A. Dodge, Jagmohan Bajaj, Brent K. Wagner, G. S. Kamath, John H. Dinan, S. D. Pearson, Roger E. DeWames |
Rok vydání: |
1996 |
Předmět: |
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Zdroj: |
SPIE Proceedings. |
ISSN: |
0277-786X |
DOI: |
10.1117/12.243457 |
Popis: |
To achieve the DoD objective of low cost high performance infrared focal plane arrays a manufacturing technique is required which is intrinsically flexible with respect to device configuration and cutoff wavelength and easily scaleable with respect to volume requirements. The approach adopted is to fully develop the technology of molecular beam epitaxy (MBE) to a level where detector array wafers with a variety of configurations can be fabricated with first pass success at a reduced cost. As a vapor phase process, MBE lends itself directly to: (1) the inclusion of real-time monitoring and process control, (2) a single or multiple wafer growth mode, (3) nearly instantaneous changes in growth parameters. A team has been assembled to carry out the program. It is composed of four industrial organizations -- Rockwell International, Hughes Aircraft Company, Texas Instruments, and Lockheed-Martin, and a university -- Georgia Tech Research Institute. Since team members are committed suppliers and users of IRFPAs, technology transfer among team members is accomplished in real-time. The technical approach has been focused on optimizing the processes necessary to fabricate p-on-n HgCdTe double layer heterostructure focal plane arrays, reducing process variance, and on documenting flexibility with respect to cutoff wavelength. Two device structures have been investigated and fabricated -- a 480 by 4 and a 128 by 128. |
Databáze: |
OpenAIRE |
Externí odkaz: |
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