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Design of large scale sensors in 180 nm CMOS process modified for radiation tolerance

The last couple of years have seen the development of Depleted Monolithic Active Pixel Sensors (DMAPS) fabricated with a process modification to increase the radiation tolerance. Two large scale prototypes, Monopix with a column drain synchronous readout, and MALTA with a novel asynchronous architec...

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Detalles Bibliográficos
Autores principales: Flores Sanz de Acedo, L, Asensi Tortajada, I, Barbero, M, Berdalovic, I, Bespin, C, Bortoletto, D, Buttar, C, Caicedo, I, Cardella, R, Dachs, F, Dao, V, Degerli, Y, Dyndal, M, Freeman, P, Habib, A, Hemperek, T, Hirono, T, Kugathasan, T, Moustakas, K, Munker, M, Pernegger, H, Piro, F, Riedler, P, Rymaszewski, P, Schioppa, E J, Schwemling, P, Sharma, A, Argemi, L Simon, Snoeys, W, Sanchez, C Solans, Wang, T, Wermes, N
Lenguaje:eng
Publicado: 2020
Materias:
Acceso en línea:https://dx.doi.org/10.1016/j.nima.2020.164403
http://cds.cern.ch/record/2729064
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author Flores Sanz de Acedo, L
Asensi Tortajada, I
Barbero, M
Berdalovic, I
Bespin, C
Bortoletto, D
Buttar, C
Caicedo, I
Cardella, R
Dachs, F
Dao, V
Degerli, Y
Dyndal, M
Freeman, P
Habib, A
Hemperek, T
Hirono, T
Kugathasan, T
Moustakas, K
Munker, M
Pernegger, H
Piro, F
Riedler, P
Rymaszewski, P
Schioppa, E J
Schwemling, P
Sharma, A
Argemi, L Simon
Snoeys, W
Sanchez, C Solans
Wang, T
Wermes, N
author_facet Flores Sanz de Acedo, L
Asensi Tortajada, I
Barbero, M
Berdalovic, I
Bespin, C
Bortoletto, D
Buttar, C
Caicedo, I
Cardella, R
Dachs, F
Dao, V
Degerli, Y
Dyndal, M
Freeman, P
Habib, A
Hemperek, T
Hirono, T
Kugathasan, T
Moustakas, K
Munker, M
Pernegger, H
Piro, F
Riedler, P
Rymaszewski, P
Schioppa, E J
Schwemling, P
Sharma, A
Argemi, L Simon
Snoeys, W
Sanchez, C Solans
Wang, T
Wermes, N
author_sort Flores Sanz de Acedo, L
collection CERN
description The last couple of years have seen the development of Depleted Monolithic Active Pixel Sensors (DMAPS) fabricated with a process modification to increase the radiation tolerance. Two large scale prototypes, Monopix with a column drain synchronous readout, and MALTA with a novel asynchronous architecture, have been fully tested and characterized both in the laboratory and in test beams. This showed that certain aspects have to be improved such as charge collection after irradiation and the output data rate. Some improvements resulting from extensive TCAD simulations were verified on a small test chip, Mini-MALTA. A detailed cluster analysis, using data from laboratory and test beam studies, at different biases, for high and low thresholds and before and after irradiation is presented, followed by detailed simulations showing that the digital architecture for both chips is capable of dealing with data rates of around 80 MHz/cm2 similar to what it is expected in the outer layer of the ATLAS inner tracker upgrade for the HL-LHC. The data rate capability and output bandwidth are studied using realistic hits generated by the ATLAS detector simulation framework.
id oai-inspirehep.net-1811865
institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2020
record_format invenio
spelling oai-inspirehep.net-18118652022-12-13T14:20:04Zdoi:10.1016/j.nima.2020.164403http://cds.cern.ch/record/2729064engFlores Sanz de Acedo, LAsensi Tortajada, IBarbero, MBerdalovic, IBespin, CBortoletto, DButtar, CCaicedo, ICardella, RDachs, FDao, VDegerli, YDyndal, MFreeman, PHabib, AHemperek, THirono, TKugathasan, TMoustakas, KMunker, MPernegger, HPiro, FRiedler, PRymaszewski, PSchioppa, E JSchwemling, PSharma, AArgemi, L SimonSnoeys, WSanchez, C SolansWang, TWermes, NDesign of large scale sensors in 180 nm CMOS process modified for radiation toleranceDetectors and Experimental TechniquesThe last couple of years have seen the development of Depleted Monolithic Active Pixel Sensors (DMAPS) fabricated with a process modification to increase the radiation tolerance. Two large scale prototypes, Monopix with a column drain synchronous readout, and MALTA with a novel asynchronous architecture, have been fully tested and characterized both in the laboratory and in test beams. This showed that certain aspects have to be improved such as charge collection after irradiation and the output data rate. Some improvements resulting from extensive TCAD simulations were verified on a small test chip, Mini-MALTA. A detailed cluster analysis, using data from laboratory and test beam studies, at different biases, for high and low thresholds and before and after irradiation is presented, followed by detailed simulations showing that the digital architecture for both chips is capable of dealing with data rates of around 80 MHz/cm2 similar to what it is expected in the outer layer of the ATLAS inner tracker upgrade for the HL-LHC. The data rate capability and output bandwidth are studied using realistic hits generated by the ATLAS detector simulation framework.oai:inspirehep.net:18118652020
spellingShingle Detectors and Experimental Techniques
Flores Sanz de Acedo, L
Asensi Tortajada, I
Barbero, M
Berdalovic, I
Bespin, C
Bortoletto, D
Buttar, C
Caicedo, I
Cardella, R
Dachs, F
Dao, V
Degerli, Y
Dyndal, M
Freeman, P
Habib, A
Hemperek, T
Hirono, T
Kugathasan, T
Moustakas, K
Munker, M
Pernegger, H
Piro, F
Riedler, P
Rymaszewski, P
Schioppa, E J
Schwemling, P
Sharma, A
Argemi, L Simon
Snoeys, W
Sanchez, C Solans
Wang, T
Wermes, N
Design of large scale sensors in 180 nm CMOS process modified for radiation tolerance
title Design of large scale sensors in 180 nm CMOS process modified for radiation tolerance
title_full Design of large scale sensors in 180 nm CMOS process modified for radiation tolerance
title_fullStr Design of large scale sensors in 180 nm CMOS process modified for radiation tolerance
title_full_unstemmed Design of large scale sensors in 180 nm CMOS process modified for radiation tolerance
title_short Design of large scale sensors in 180 nm CMOS process modified for radiation tolerance
title_sort design of large scale sensors in 180 nm cmos process modified for radiation tolerance
topic Detectors and Experimental Techniques
url https://dx.doi.org/10.1016/j.nima.2020.164403
http://cds.cern.ch/record/2729064
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