Destructive breakdown studies of irradiated LGADs at beam tests for the ATLAS HGTD

Beresford, L. A.; Boumediene, D. E.; Garcia, L. Castillo; Corpe, L. D.; de Sousa, M. J. Da Cunha Sargedas; El Jarrari, H.; Eshkevarvakili, A.; Grieco, C.; Grinstein, S.; Guindon, S.; Howard, A.; Kramberger, G.; Kurdysh, O.; Mazini, R.; Missio, M.; Morenas, M.; Perrin, O.; Raskina, V.; Saito, G.; Trincaz-Duvoid, S.

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Author(s): Show less -	Beresford, L. A. ; Boumediene, D. E. ; Garcia, L. Castillo ; Corpe, L. D. ; de Sousa, M. J. Da Cunha Sargedas ; El Jarrari, H. ; Eshkevarvakili, A. ; Grieco, C. ; Grinstein, S. ; Guindon, S. ; Howard, A. ; Kramberger, G. ; Kurdysh, O. ; Mazini, R. ; Missio, M. ; Morenas, M. ; Perrin, O. ; Raskina, V. ; Saito, G. ; Trincaz-Duvoid, S. Total Authors: 20
Document type:	Journal article
Source:	Journal of Instrumentation; v. 18, n. 7, p. 15-pg., 2023-07-01.
Abstract
In the past years, it has been observed at several beam test campaigns that irradiated LGAD sensors break with a typical star shaped burn mark when operated at voltages much lower than those at which they were safely operated during laboratory tests. The study presented in this paper was designed to determine the safe operating voltage that these sensors can withstand. Many irradiated sensors from various producers were tested in two test beam facilities, DESY (Hamburg) and CERN-SPS (Geneva), as part of ATLAS High Granularity Timing Detector (HGTD) beam tests. The samples were placed in the beam and kept under bias over a long period of time in order to reach a high number of particles crossing each sensor. Both beam tests lead to a similar conclusion, that these destructive events begin to occur when the average electric field in the sensor becomes larger than 12 V/mu m. (AU)

FAPESP's process:	20/04867-2 - High energy physics and instrumentation with the LHC-CERN
Grantee:	Marcelo Gameiro Munhoz
Support Opportunities:	Special Projects

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