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Thermal Stability in HgCdTe IR Photodiodes

Published online by Cambridge University Press:  11 February 2011

J. M. Dell ,
T. Nguyen ,
C. A. Musca ,
J. Antoszewski ,
L. Faraone  and
R. Pal
J. M. Dell
Affiliation:
School of Electrical, Electronic and Computer Engineering, The University of Western Australia, Crawley, 6009, Australia
T. Nguyen
Affiliation:
School of Electrical, Electronic and Computer Engineering, The University of Western Australia, Crawley, 6009, Australia
C. A. Musca
Affiliation:
School of Electrical, Electronic and Computer Engineering, The University of Western Australia, Crawley, 6009, Australia
J. Antoszewski
Affiliation:
School of Electrical, Electronic and Computer Engineering, The University of Western Australia, Crawley, 6009, Australia
L. Faraone
Affiliation:
School of Electrical, Electronic and Computer Engineering, The University of Western Australia, Crawley, 6009, Australia
R. Pal
Affiliation:
Now at Solid State Physics Laboratory, Timarpur, Delhi, India
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Abstract

Packaging of HgCdTe photodiode detector arrays in a dewar involves degassing at elevated temperatures for several days so as to achieve vacuum integrity. This sustained exposure to relatively high temperatures can influence the HgCdTe bulk material properties, p-n junction integrity, and the passivant-HgCdTe interface. This work investigates the effects of bake-out treatment on the performance of HgCdTe based photodiodes formed using a new plasma induced type conversion process. Experimental results of a series of experiments in both long-wavelength infrared (LWIR) and mid-wavelength infrared (MWIR) devices are presented.

Bulk lifetime was used as an indicator of the change in the bulk material resulting from baking in vacuum and was measured by photoconductive decay. These measurements did not show any appreciable changes as a result of baking. Modification of the doping profile in the n-p junction may also result from high temperature baking. Doping profiles of the photodiodes were studied by measuring the junction capacitance-voltage relation before and after baking. The results of these tests after baking showed no changes to C-V measurements from those before bake.

The effect of baking on the passivant/HgCdTe interface was also examined by carrying out surface recombination velocity measurements by photoconductive decay on samples with different passivation layers.

Variable area HgCdTe photodiodes have also been fabricated and studied to understand the effect of the surface condition of the performance of the devices. Initial bake tests on LWIR devices show that the technology is stable when employing a double layer passivation technique. Bake tests on the more advanced MWIR technology indicates that the plasma induced type conversion process produces stable photodiodes with state of the art performance.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 744: Symposium M – Progress in Semiconductors II–Electronic and Optoelectronic Applications , 2002 , M9.6
Copyright
Copyright © Materials Research Society 2003

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References

REFERENCES

[1] Miller, J.L., Principles of Infrared Technology, Van Nostrand Reinhold, New York, (1994), p. 135 Google Scholar
[2] Dell, J. M., Antoszewski, J., Rais, M. H., Musca, C. A., Nener, B. D., Faraone, L., J. Electron. Mat, 29, 841, (2000)Google Scholar
[3] Belas, E., Franc, J., Toth, A., Moravac, P., Grill, R., Sitter, H., Hoschl, P., Semicond. Sci. Techno.l, 11, 1116, (1996)Google Scholar
[4] Pearton, S. J., SPIE Vol. 2999, 118, (1997)Google Scholar
[5] Belas, E., Franc, J., Toth, A., Moravec, P., Grill, R., Sitter, H., Hoschl, P., Semicond. Sci. Technol. 11, 1116 (1996)Google Scholar
[6] Nguyen, T., Antoszewski, J., Musca, C. A., Redfern, D. A., Dell, J. M., Faraone, L., J. Electron. Mat., 31 (7), 653, (2002)Google Scholar
[7] White, J. K., Antoszewski, J., Pal, R., Musca, C. A., Dell, J. M., Faraone, L., Piotrowski, J., J. Electron. Mat., 31 (7), 743, (2002)Google Scholar
[8] Bajaj, J., Arias, J. M., Zandian, M., Pasko, J. G., Kozlowski, L. J., DeWarmes, R. E., Tennant, W. E., J. Electron. Mat., 24 (9), 1067, (1995)Google Scholar
[9] De Lyon, T. J., Rajavel, R. D., Jensen, J. E.. Wu, O. K., Johnson, S. M., Cockrum, C. A., Venzor, G. M., J. Electron. Mat., 25 (8), 1341, (1996)Google Scholar
[10] White, J. K., Musca, C. A., Lee, H. C., Faraone, L., Appl. Phys. Lett., 76, 17, pp. 24482450 (2000)Google Scholar
[11] Lopes, V. C., Wright, W. H., Syllaios, A. J., J. Vac. Sci. Technol. A 8 (2), 1167 (1990)Google Scholar
[12] Ajisawa, A., Oda, N., J. Electron. Mater., 24 (9), 1105, (1995)Google Scholar
[13] Ashokan, R., Dhar, N. K., Yang, B., Akhiyat, A., Lee, T. S., Rujirawat, S., Yousuf, S., Sivananthan, S., J. Electron. Mat. 31, 656 (2002)Google Scholar