Title :
Charge transfer efficiency in proton damaged CCD´s
Author :
Hardy, T. ; Murowinski, R. ; Deen, M.J.
Author_Institution :
Sch. of Eng. Sci., Simon Fraser Univ., Burnaby, BC, Canada
fDate :
4/1/1998 12:00:00 AM
Abstract :
We have performed detailed measurements of the charge transfer efficiency (CTE) in a thinned, backside-illuminated imaging charge-coupled device (CCD). The device had been damaged in three separate sections by proton radiation typical of that which a CCD would receive in space-borne experiments, nuclear imaging, or particle detection. We examined CTE as a function of signal level, temperature, and radiation dose. The dominant factor affecting the CTE in radiation-damaged CCD´s is seen to be trapping by bulk states. We present a simple physical model for trapping as a function of transfer rate, trap concentration, and temperature. We have made calculations using this model and arrived at predictions which closely match the measured results. The CTE was also observed to have a nonlinear dependence on signal level. Using two-dimensional device simulations to examine the distribution of the charge packets in the CCD channel over a range of signal levels, we were able to explain the observed variation
Keywords :
CCD image sensors; electron traps; hole traps; proton effects; CCD channel; bulk states; charge transfer efficiency; dominant factor; nuclear imaging; particle detection; proton damaged CCD; radiation dose; space-borne experiments; temperature; thinned backside-illuminated imaging charge-coupled device; transfer rate; trap concentration; two-dimensional device simulations; Charge coupled devices; Charge measurement; Charge transfer; Current measurement; Nuclear imaging; Performance evaluation; Predictive models; Protons; Radiation detectors; Temperature;
Journal_Title :
Nuclear Science, IEEE Transactions on
