Super-radiation hard detector technologies: 3-D and widegap detectors

Super-radiation hard detector technologies: 3-D and widegap detectors

The radiation hardness of semiconductor detectors for harsh environments, including nuclear, space, and particle physics, may be enhanced by a number of strategies. We examine the use of materials alternative to silicon, namely silicon carbide and gallium nitride, as well as a nonconventional geomet...

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Veröffentlicht in:IEEE transactions on nuclear science 2004-10, Vol.51 (5), p.2256-2261
Hauptverfasser: Rahman, M., Al-Ajili, A., Bates, R., Blue, A., Cunningham, W., Doherty, F., Glaser, M., Haddad, L., Horn, M., Melone, J., Mikuz, M., Quinn, T., Roy, P., O'Shea, V., Smith, K.M., Vaitkus, J., Wright, V.
Format: Artikel
Sprache:eng
Schlagworte:
Charge measurement
Current measurement
Gallium nitride
Geometry
III-V semiconductor materials
Radiation detectors
Semiconductor materials
Semiconductor radiation detectors
Silicon carbide
Space technology
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Zusammenfassung:The radiation hardness of semiconductor detectors for harsh environments, including nuclear, space, and particle physics, may be enhanced by a number of strategies. We examine the use of materials alternative to silicon, namely silicon carbide and gallium nitride, as well as a nonconventional geometry called "3-D." Fabricated detectors were irradiated to fast hadron fluences of 10/sup 14/ cm/sup -2/ and measurements were made of I--V, C--V and charge collection efficiency before and after irradiation. The performance in each case was found to degrade only slightly, promising highly radiation tolerant operation.
ISSN:0018-9499
1558-1578
DOI:10.1109/TNS.2004.835902