Ústav technické a experimentální fyziky Institute of Experimental and Applied Physics

Evaluation of local radiation damage in silicon sensor via charge collection mapping with the Timepix read-out chip

NázevTitle
Evaluation of local radiation damage in silicon sensor via charge collection mapping with the Timepix read-out chipEvaluation of local radiation damage in silicon sensor via charge collection mapping with the Timepix read-out chip
Druh výsledkuResult type
Článek v časopiseJournal article
AutořiAuthors
M. Platkevič, J. Jakůbek, V. Havránek, M. Jakůbek, S. Pospíšil, V. Semian, J. Žemlička
DOIDOI
10.1088/1748-0221/8/04/C04001
Časopis / citaceJournal / citation
Journal of Instrumentation. 2013, 8(04), ISSN 1748-0221.
RokYear
2013
JazykLanguage
eng
WoSWoS
000317462400001
ScopusScopus
2-s2.0-84877724574
RIVRIV
RIV/68407700:21670/13:00215465!RIV14-TA0-21670___
ProjektProject
Centrum pokročilých jaderných technologiíCentre for Advanced Nuclear Technologies; Pracoviště pro nedestruktivní testování, diagnostiku a 3D zobrazování pomocí neutronové radiografie a tomografie (2011-2015, TA0/TA)Facility for nondestructive testing, diagnostics and 3D imaging based on neutron radiography and tomography.

AbstraktAbstract

Studies of radiation hardness of silicon sensors are standardly performed with single-pad detectors evaluating their global electrical properties. In this work we introduce a technique to visualize and determine the spatial distribution of radiation damage across the area of a semiconductor sensor. The sensor properties such as charge collection efficiency and charge diffusion were evaluated locally at many points of the sensor creating 2D maps. For this purpose we used a silicon sensor bump bonded to the pixelated Timepix read-out chip. This device, operated in Time-over-threshold (TOT) mode, allows for the direct energy measurement in each pixel. Selected regions of the sensor were intentionally damaged by defined doses (up to 10(12) particles/cm(2)) of energetic protons (of 2.5 and 4 MeV). The extent of the damage was measured in terms of the detector response to the same ions. This procedure was performed either on-line during irradiation or off-line after it. The response of the detector to each single particle was analyzed determining the charge collection efficiency and lateral charge diffusion. We evaluated the changes of these parameters as a function of radiation dose. These features are related to the local properties such as the spatial homogeneity of the sensor. The effect of radiation damage was also independently investigated measuring local changes of signal response to gamma, and X rays and alpha particles.

Studies of radiation hardness of silicon sensors are standardly performed with single-pad detectors evaluating their global electrical properties. In this work we introduce a technique to visualize and determine the spatial distribution of radiation damage across the area of a semiconductor sensor. The sensor properties such as charge collection efficiency and charge diffusion were evaluated locally at many points of the sensor creating 2D maps. For this purpose we used a silicon sensor bump bonded to the pixelated Timepix read-out chip. This device, operated in Time-over-threshold (TOT) mode, allows for the direct energy measurement in each pixel. Selected regions of the sensor were intentionally damaged by defined doses (up to 10(12) particles/cm(2)) of energetic protons (of 2.5 and 4 MeV). The extent of the damage was measured in terms of the detector response to the same ions. This procedure was performed either on-line during irradiation or off-line after it. The response of the detector to each single particle was analyzed determining the charge collection efficiency and lateral charge diffusion. We evaluated the changes of these parameters as a function of radiation dose. These features are related to the local properties such as the spatial homogeneity of the sensor. The effect of radiation damage was also independently investigated measuring local changes of signal response to gamma, and X rays and alpha particles.