Hostname: page-component-586b7cd67f-rdxmf Total loading time: 0 Render date: 2024-11-25T17:40:47.178Z Has data issue: false hasContentIssue false
  • English
  • Français

Recombination Activity of Individual Extended Defects in Silicon

Published online by Cambridge University Press:  03 September 2012

A. Cavallini  and
A. Castaldini
A. Cavallini
Affiliation:
University of Bologna, Dept. of Physics, Via Irnerio 46, 1–40126 Bologna, Italy.
A. Castaldini
Affiliation:
University of Bologna, Dept. of Physics, Via Irnerio 46, 1–40126 Bologna, Italy.
Get access

Abstract

Dislocations and point defects introduce energy levels deep in the gap, which dramatically change the material electrical properties. Because of the coexistence of a multitude of dislocation types and dislocation-point defect interaction mechanisms, it would be highly desirable to identify the particular type of defect related to specific traps.

The electrical activity of extended defects (planar precipitates and dislocations) is here examined in terms of their recombination activity, investigated by electron as well as light beam induced current methods of scanning microscopy.

Besides, a scanning modification of spectroscopy is used to identify traps at individual defects. The method, named quenched infra-red beam induced current, combines the scanning light beam induced current technique with the spectroscopie bulk analysis called “infrared quenching of photoconductivity”.

Defect energy levels are found on the basis of the particular features of the beam induced current as a function of injected carrier generation rate, temperature and quenching excitation.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 262: Symposium E – Defect Engineering in Semiconductor Growth, Processing and Device Technology , 1992 , 223
Copyright
Copyright © Materials Research Society 1992

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

REFERENCES

1. Wilshaw, P. R., Fell, T. S. and Booker, G. R., in Point and Extended Defects in Semiconductors, edited by Benedek, G., Cavallini, A. and Schröter, W. (Plenum Press NATO ASI series B202, 1988) p. 243.Google Scholar
2. Wilshaw, P. R. and Fell, T. S., in Structure and Properties of Dislocations in Semiconductors, edited by Roberts, S.G., Holt, D.B. and Wilshaw, P.R. (Institute of Physics Conference Series N. 104, Bristol and New York, 1989), p. 85.Google Scholar
3. Bondarenko, I. E. and Yakimov, E. B., Phys. Stat. Sol. (a) 122, 121 (1990).Google Scholar
4. Sieber, B., in Gettering and Defect Engineering in Semiconductor Technolog Y, edited by Kittler, M. and Richter, H., (Trans Tech Publication, Solid State Phenomena 19 & 20, 1991), p. 353.Google Scholar
5. Leamy, H. J., J. Appl. Phys. 52 (6), R51 (1982).CrossRefGoogle Scholar
6. Wilson, T. and Sheppard, C. J. R., Scanning Optical Microscopy, (Academic Press, London 1984).Google Scholar
7. Castaldini, A. and Cavallini, A., in Point and Extended Defects in Semiconductors, edited by Benedek, G., Cavallini, A. and Schröter, W. (Plenum Press NATO ASI series B202, 1988) p. 257.Google Scholar
8. Castaldini, A. and Cavallini, A., in Scanning Microscopy Tecnologies and Applications, edited Teague, E.C. (SPIE Publishers, Washington Vol. 897, 1988), p. 55.CrossRefGoogle Scholar
9. Castaldini, A., Cavallini, A., Poggi, A. and Susi, E., Appl. Phys. A 48, 431 (1989).CrossRefGoogle Scholar
10. Gleichmann, R., Blumtritt, H. and Heydenreich, J., Phys. Stat. Sol. (a) 78, 527 (1983).CrossRefGoogle Scholar
11. Blumtritt, H., Kittler, M. and Seifert, W., in Structure and Properties of Dislocations in Semiconductors, edited by Roberts, S.G., Holt, D.B. and Wilshaw, P.R. (Institute of Physics Conference Series N. 104, Bristol and New York, 1989), p. 233.Google Scholar
12. Leamy, J., Kimerling, L. C. and Ferris, S. D., in Scanning Electron Microscopy, edited by Johari, O. (I.I.T. Res. Inst., Chicago, 1976) p. 529.Google Scholar
13. Das, G., J. Appl. Phys. 44, 4459 (1973).Google Scholar
14. Bondarenko, I. E. and Yakimov, E. B., in Microscopy of Semiconducting Materials edited by Cullis, A.G. and Long, N.J. (Institute of Physics Conference 117, 1991), p. 743.Google Scholar
15. Norman, C. E. and Holt, D. B., in Microscopy of Semiconducting Materials, edited by Cullis, A. G. and Long, N. J. (Institute of Physics Conference 117), p. 755.Google Scholar
16. Cavallini, A. and Castaldini, A., in Beam Injection Assessment of Defects in Semiconductors, edited by Sieber, B., Farvacque, J. L., Castaing, J., Imhoff, D., Marfaing, Y. and Maurice, J. L., (Journal de Physique IV C6 1991), p. C689.Google Scholar
17. Alexander, H. and Teichler, H., in Electronic Structure and Properties of Semiconductors, edited by Schroter, W., (Weinheim, VCH, Vol 14, 1991), p. 249.Google Scholar
18. Omling, P., Weber, E. R., Montelius, L., Alexander, H. and Michel, J., Phys. Rev. B32. 6571 (1985).CrossRefGoogle Scholar