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Large Area Silicon Avalanche Photodiodes: Photomultiplier Tube Alternate

Published online by Cambridge University Press:  15 February 2011

G. Reiff ,
M.R. Squillante ,
H.B. Serreze ,
G. Entine  and
Gerald C. Huth
G. Reiff
Affiliation:
Radiation Monitoring Devices, Inc., 44 Hunt St., Watertown, MA 02172(617) 926-1167
M.R. Squillante
Affiliation:
Radiation Monitoring Devices, Inc., 44 Hunt St., Watertown, MA 02172(617) 926-1167
H.B. Serreze
Affiliation:
Radiation Monitoring Devices, Inc., 44 Hunt St., Watertown, MA 02172(617) 926-1167
G. Entine
Affiliation:
Radiation Monitoring Devices, Inc., 44 Hunt St., Watertown, MA 02172(617) 926-1167
Gerald C. Huth
Affiliation:
USC Medical Imaging Service, 4676 Admiralty Way, Marina del Rey, CA 90291
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Abstract

Silicon avalanche photodiodes have recently been shown to be a potential replacement for vacuum tube photomultipliers in many nuclear scintillation detector applications. The large active area, low noise, and ease of use of these solid-state photomultipliers makes them ideally suited to scintillation detector applications where overall size and ruggedness are a major concern. Historically, avalanche photodiodes have been limited for use in this capacity by small active areas, low internal gains, and poor optical sensitivity at the wavelengths at which most solid scintillator materials emit. Recent advances as the result of research aimed directly at the solution to these problems however, have successfully demonstrated one inch active area silicon avalanche photodiodes which produce a FWHM resolution of 9.5% for Cs137 at room temperature when coupled to a 1″ × 1″ NaI(Tl) scintillation crystal. Improvements to both material quality and device structure have advanced the state-of-the-art to make silicon avalanche photodiodes a viable alternative in scintillation gamma spectroscopy as well as for large area optical, beta, and low energy x-ray detectors.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 16: Symposium – F Nuclear Radiation Detector Materials , 1982 , 131
Copyright
Copyright © Materials Research Society 1983

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References

REFERENCES

1. Webb, P. P., McIntyre, R. J. and Conradio, J., RCA Review 35, 234 (1974).Google Scholar
2. McIntyre, R. J., IEEE Trans. Electron Devices ED-19, 703 (1972).CrossRefGoogle Scholar
3. “Research on Avalanche Type Semiconductor Radiaton Detectors”, Gerald C. Huth, Peter V. Hewlsa and Vincent L. Gelezunas, Report Code NYO:3246TA-6 (Jan. 1970).Google Scholar
4. General Electric space Technology Products, (sales brochure data sheet) GE-STP (7-70).Google Scholar
5. Sze, S. M., Physics of Semiconductor Devices, Second Edition, Wiley-Interscience, new York (1981).Google Scholar