- Lazarus effect
When using
semiconductor detector s in harshradiation environments, defects begin to appear in the semiconductorcrystal lattice asatom s become displaced because of the interaction with the high-energy traversing particles. These defects, in the form of both lattice vacancies and atoms at interstitial sites, have the effect of temporarily trapping theelectron s and holes which are created when ionizing particles pass through the detector. Since it is theseelectron s and holes which drifting under anelectric field produce a signal announcing the passage of a particle, when large amounts of defects are produced, detector signal can be strongly reduced leading to an unusable (dead) detector.However in 1997, Dr. Vittorio Palmieri and co-workers at the
University of Berne (Switzerland) found out that at temperatures below 130kelvin s (about −143 degreesCelsius ), dead detectors apparently come back to life. The explanation of this phenomenon, known as the Lazarus Effect, is related to the dynamics of the induced defects in thesemiconductor bulk.At room temperature
radiation damage induced defects temporarily trapelectron s and holes resulting fromionization , which are then emitted back to theconduction band orvalence band in a time that is typically longer than the read-out time of the connected electronics. Consequently the measured signal is smaller that it should be. This leads to lowsignal to noise ratio s that in turn can prevent the detection of the traversing particle.Atcryogenic temperature s, however, once anelectron or hole, resulting fromionization or from detectorleakage current, is trapped in a local defect, it remains trapped for a long time due to the very lowthermal energy of thelattice . This leads to a large fraction of 'traps' becoming filled and therefore inactive. Trapping ofelectron s and holes generated by particles traversing the detector is then prevented and no or little signal is lost.References
* “Evidence for charge collection efficiency recovery in heavily irradiated silicon detectors operated at cryogenic temperatures” V.G. Palmieri, K. Borer, S. Janos, C. Da Viá, L. Casagrande; Nucl. Instr. and Meth. in Phys. Res A, Vol. 413, pp. 475-478, (1998)
External links
* http://www.hip.fi/research/cms/tracker/RD39 RD39 Collaboration Web Page
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