Hostname: page-component-78c5997874-lj6df Total loading time: 0 Render date: 2024-11-14T07:21:50.704Z Has data issue: false hasContentIssue false

Statistical Analysis of Micropipe Defect Distributions in Silicon Carbide Crystals

Published online by Cambridge University Press:  01 February 2011

Troy Elkington
Affiliation:
II-VI Inc., Saxonburg PA
Ejiro Emorhokpor
Affiliation:
II-VI Inc., Pine Brook NJ
Tom Kerr
Affiliation:
II-VI Inc., Pine Brook NJ
John Chen
Affiliation:
II-VI Inc., Saxonburg PA
Kevin Essary
Affiliation:
II-VI Inc., Saxonburg PA
Mike Golab
Affiliation:
II-VI Inc., Saxonburg PA
Richard H. Hopkins
Affiliation:
II-VI Inc., Saxonburg PA
Get access

Abstract

The density and distribution of micropipes (MPD's), a screw dislocation with a hollow core, are significant criteria for SiC wafer selection in device fabrication. For this reason the measurement of micropipes in SiC is an important problem. The micropipe distributions of 2’’ diameter 6H SiC wafers from three different PVT furnace designs in three different laboratories were statistically characterized. The micropipe distributions were measured in two ways: by KOH etching the wafer and then counting the hexagonal pits formed on the wafer surface using a microscope and imaging software; and by manually counting with an optical transmission microscope the micropipes on a un-etched wafer within a grid of 0.5mm squares superimposed over the wafer. None of the wafers had a random distribution of micropipes i.e. they did not follow a Poisson distribution. The micropipes were found to associate with each other i.e. there is a higher probability of there being other micropipes near a location where a micropipe has been found. In the eight samples characterized, 1.9% of the wafer area contained 32% of the total micropipes. We have analyzed the repeatability of the optical transmission microscopy method of micropipe characterization and found that it is dependent on the micropipe density; the standard deviation of the measurement increases with increasing MPD. The number of micropipes counted increases by about 10% with increasing magnification and 15% when the wafer is double side polished.

Type
Research Article
Copyright
Copyright © Materials Research Society 2003

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] Koga, K., Fujikawa, Y., Ueda, Y., and Yamaguchi, T., Springer Proc. in Phys.. In: Amorphous and Crystalline Silicon Carbide IV, vol. 71, Springer, Berlin, 1992, p. 96.Google Scholar
[2] Ha, S., Vetter, W.M., Dudley, M., and Skowronski, M., Mat. Sci. Forum 389-393 (2002) p. 443.Google Scholar
[3] Amelinckx, S., Strumane, G., Webb, W., J. App. Phys. 31 No. 8 (1960) p. 1359 Google Scholar
[4] Dudley, M., Wang, S., Huang, W., Carter, C. Jr, Tsvetkov, V.F., and Fazi, C., J. Phys. D: Appl. Phys. 28 (1995) p. A63 Google Scholar
[5] Dudley, M., Si, W., Wang, S., Carter, C. Jr, Glass, R., and Tsvetkov, V., IL Nuovo Cimento 19 (1997) p. 153 Google Scholar
[6] Ma, X., Parker, M., Ma, Y., Kubota, T., Sudarshan, T., Proceedings of ECSCRM2002,Google Scholar
[7] “Experimental Design and Industrial Statistics” a course by Luftig, J. T. and , Warren.Google Scholar
[8] See most standard statistic texts. An example “An introduction to statistical methods and data analysis” by Ott, Lyman, PWS-Kent 1988 Google Scholar
[9] Frank, F. C., Acta Cryst., 4 (1951) 497.Google Scholar
[10] Muller, St. G., Glass, R., Hobgood, H., Tsvetkov, V., Brady, M., Henshall, D., Malta, D., Singh, R., Palmour, J., Carter, C., Mat. Sci. Eng. B80 (2001) p. 327 Google Scholar