TY - GEN
T1 - Atomic force microscopy investigation of dislocation structures and deformation characteristics in neutron irradiated silicon detectors
AU - Golan, G.
AU - Rabinovich, E.
AU - Inberg, A.
AU - Axelevitch, A.
AU - Oksman, M.
AU - Rosenwaks, Y.
AU - Kozlovsky, A.
AU - Rancoita, P. J.
AU - Rattagi, M.
AU - Seidman, A.
AU - Croitoru, N.
PY - 2000
Y1 - 2000
N2 - The structure, microhardness and deformation character for silicon detectors were investigated following a neutron irradiation, using optical and Atomic Force (AFM) microscopes. The results of these investigations have given an important contribution to the understanding of silicon damage process by neutron irradiation. It was shown that in the interval of neutron fluences 9.9×1010≤Φ≤3.12×1015 n/cm 2 the damage is accumulative (from small punctual to large defects). The abrupt changes of microstructure together with the electrical and mechanical properties were found for Φ≥1014n/cm2 Different kinds of defects (dislocations and interstitials) and their complexes appeared under neutron irradiation. For all fluences the regions ("White" -"W") with a microhardness smaller than in nonirradiated silicon were observed. Microhardness is larger in the regions where the concentration of dislocation loops is high. The "W", regions have a small number of the dislocations loops, and single punctual defects were seen there using Atomic Force Microscope. The dislocation loops are placed in specific ("Black"-"B") regions, which increase in size with the increase of neutron fluence due to a process of vacancies and interstitials accumulation.
AB - The structure, microhardness and deformation character for silicon detectors were investigated following a neutron irradiation, using optical and Atomic Force (AFM) microscopes. The results of these investigations have given an important contribution to the understanding of silicon damage process by neutron irradiation. It was shown that in the interval of neutron fluences 9.9×1010≤Φ≤3.12×1015 n/cm 2 the damage is accumulative (from small punctual to large defects). The abrupt changes of microstructure together with the electrical and mechanical properties were found for Φ≥1014n/cm2 Different kinds of defects (dislocations and interstitials) and their complexes appeared under neutron irradiation. For all fluences the regions ("White" -"W") with a microhardness smaller than in nonirradiated silicon were observed. Microhardness is larger in the regions where the concentration of dislocation loops is high. The "W", regions have a small number of the dislocations loops, and single punctual defects were seen there using Atomic Force Microscope. The dislocation loops are placed in specific ("Black"-"B") regions, which increase in size with the increase of neutron fluence due to a process of vacancies and interstitials accumulation.
UR - http://www.scopus.com/inward/record.url?scp=84906824742&partnerID=8YFLogxK
U2 - 10.1109/ICMEL.2000.840590
DO - 10.1109/ICMEL.2000.840590
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AN - SCOPUS:84906824742
SN - 0780352351
SN - 9780780352353
T3 - 2000 22nd International Conference on Microelectronics, MIEL 2000 - Proceedings
SP - 363
EP - 366
BT - 2000 22nd International Conference on Microelectronics, MIEL 2000 - Proceedings
PB - IEEE Computer Society
T2 - 2000 22nd International Conference on Microelectronics, MIEL 2000
Y2 - 14 May 2000 through 17 May 2000
ER -