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Performance of P-I-N CdZnTe Radiation Detectors and Their Unique Advantages

Published online by Cambridge University Press:  10 February 2011

R. Sudharsanan ,
C. C. Stenstrom ,
P. Bennett  and
G. D. Vakerlis
R. Sudharsanan
Affiliation:
Spire Corporation, One Patriots Park, Bedford, MA, 01730-2396
C. C. Stenstrom
Affiliation:
Spire Corporation, One Patriots Park, Bedford, MA, 01730-2396
P. Bennett
Affiliation:
Radiation Monitoring Devices, Watertown, MA
G. D. Vakerlis
Affiliation:
Spire Corporation, One Patriots Park, Bedford, MA, 01730-2396
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Abstract

We present the performance characteristics of CdZnTe radiation detectors with a new P-I-N design and their unique advantages over metal-semiconductor-metal (M-S-M) devices. In M-S-M CdZnTe detectors the bulk resistivity of the substrate largely determines the leakage current. High leakage current is a dominant noise factor for CdZnTe detector arrays, coplanar detectors, and detectors used for low X-ray energy applications. P-I-N devices provide low leakage currents. Early CdZnTe detectors exhibited polarization, were limited to small detection volumes, and some required high deposition temperatures. We have developed a new heterojunction design which can be deposited at low temperatures so that even high-pressure Bridgman CdZnTe can be used. Using the P-I-N design, CdZnTe detectors with high detection volumes (>200 mm3) were fabricated and exhibited low leakage current, good energy resolution, and no polarization. These detectors have significant advantages over M-S-M detectors in three specific areas. First, X-ray fluorescence studies require detectors with low leakage currents to provide less spectral broadening due to electronic noise. Second, less expensive vertical Bridgman CdZnTe material can be used for imaging applications since it normally possesses too low of a bulk resistivity to be useful as a M-S-M detector. Third, leakage currents across the anode grid in large volume coplanar detectors can be significantly reduced

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 487: Symposium I – Semiconductors for Room-Temperature Radiation II , 1997 , 245
Copyright
Copyright © Materials Research Society 1998

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