DocumentCode
1139204
Title
Radiation Hardness and Charge Collection Efficiency of Lithium Irradiated Thin Silicon Diodes
Author
Boscardin, Maurizio ; Bruzzi, Mara ; Candelori, Andrea ; Betta, Gian-Franco Dalla ; Focardi, Ettore ; Khomenkov, Volodymyr ; Piemonte, Claudio ; Ronchin, Sabina ; Tosi, Carlo ; Zorzi, Nicola
Author_Institution
ITC-irst Microsystems Div., Povo Di Trento, Italy
Volume
52
Issue
4
fYear
2005
Firstpage
1048
Lastpage
1053
Abstract
Due to their low depletion voltage, even after high particle fluences, improved tracking precision and momentum resolution, and reduced material budget, thin substrates are one of the possible choices to provide radiation hard detectors for future high energy physics experiments. In the framework of the CERN RD50 Collaboration, we have developed PIN diode detectors on membranes obtained by locally thinning the silicon substrate by means of TMAH etching from the wafer backside. Diodes of different shapes and sizes have been fabricated on 50- 
and 100- thick membranes and tested, showing a low leakage current (of 300 
) and a very low depletion voltage (in the order of 1 V for the 50 membrane) before irradiation. Radiation damage tests have been performed with 58 MeV lithium (Li) ions up to the fluence of 
in order to determine the depletion voltage and leakage current density increase after irradiation. Charge collection efficiency tests carried out with a 
particle source have been performed on both nonirradiated devices and samples irradiated up to 
. Results reported here confirm the advantages of thinned diodes with respect to standard 300- thick devices in terms of low depletion voltage and high charge collection efficiency.
and 100- thick membranes and tested, showing a low leakage current (of 300 ) and a very low depletion voltage (in the order of 1 V for the 50 membrane) before irradiation. Radiation damage tests have been performed with 58 MeV lithium (Li) ions up to the fluence of in order to determine the depletion voltage and leakage current density increase after irradiation. Charge collection efficiency tests carried out with a particle source have been performed on both nonirradiated devices and samples irradiated up to . Results reported here confirm the advantages of thinned diodes with respect to standard 300- thick devices in terms of low depletion voltage and high charge collection efficiency.Keywords
beta-ray sources; etching; ion beam effects; leakage currents; p-i-n diodes; position sensitive particle detectors; silicon radiation detectors; 100 micron; 50 micron; 58 MeV; CERN RD50 Collaboration; PIN diode detectors; TMAH etching; beta particle source; charge collection efficiency; depletion voltage; high energy physics experiments; leakage current; lithium irradiated thin silicon diodes; membranes; momentum resolution; nonirradiated devices; radiation damage; radiation hardness; silicon substrate; Biomembranes; Diodes; Energy resolution; Leakage current; Lithium; Low voltage; Particle tracking; Performance evaluation; Silicon; Testing; Charge collection efficiency; TMAH; lithium ion; radiation damage; silicon detectors;
fLanguage
English
Journal_Title
Nuclear Science, IEEE Transactions on
Publisher
ieee
ISSN
0018-9499
Type
jour
DOI
10.1109/TNS.2005.852721
Filename
1495804
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