Digital Pixel Test Structures implemented in a 65 nm CMOS process

The ALICE ITS3 (Inner Tracking System 3) upgrade project and the CERN EP R&D on monolithic pixel sensors are investigating the feasibility of the Tower Partners Semiconductor Co. 65nm process for use in the next generation of vertex detectors. The ITS3 aims to employ wafer-scale Monolithic Activ...

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Autores principales: Rinella, Gianluca Aglieri, Andronic, Anton, Antonelli, Matias, Aresti, Mauro, Baccomi, Roberto, Becht, Pascal, Beole, Stefania, Braach, Justus, Buckland, Matthew Daniel, Buschmann, Eric, Camerini, Paolo, Carnesecchi, Francesca, Cecconi, Leonardo, Charbon, Edoardo, Contin, Giacomo, Dannheim, Dominik, de Melo, Joao, Deng, Wenjing, di Mauro, Antonello, Hasenbichler, Jan, Hillemanns, Hartmut, Hong, Geun Hee, Isakov, Artem, Junique, Antoine, Kluge, Alex, Kotliarov, Artem, Křížek, Filip, Lautner, Lukas, Mager, Magnus, Marras, Davide, Martinengo, Paolo, Masciocchi, Silvia, Menzel, Marius Wilm, Munker, Magdalena, Piro, Francesco, Rachevski, Alexandre, Rebane, Karoliina, Reidt, Felix, Russo, Roberto, Sanna, Isabella, Sarritzu, Valerio, Senyukov, Serhiy, Snoeys, Walter, Sonneveld, Jory, Šuljić, Miljenko, Svihra, Peter, Tiltmann, Nicolas, Usai, Gianluca, Van Beelen, Jacob Bastiaan, Vassilev, Mirella Dimitrova, Vernieri, Caterina, Villani, Anna
Lenguaje:eng
Publicado: 2022
Materias:
physics.ins-det
Detectors and Experimental Techniques
Acceso en línea:https://dx.doi.org/10.1016/j.nima.2023.168589
http://cds.cern.ch/record/2845385
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author Rinella, Gianluca Aglieri
Andronic, Anton
Antonelli, Matias
Aresti, Mauro
Baccomi, Roberto
Becht, Pascal
Beole, Stefania
Braach, Justus
Buckland, Matthew Daniel
Buschmann, Eric
Camerini, Paolo
Carnesecchi, Francesca
Cecconi, Leonardo
Charbon, Edoardo
Contin, Giacomo
Dannheim, Dominik
de Melo, Joao
Deng, Wenjing
di Mauro, Antonello
Hasenbichler, Jan
Hillemanns, Hartmut
Hong, Geun Hee
Isakov, Artem
Junique, Antoine
Kluge, Alex
Kotliarov, Artem
Křížek, Filip
Lautner, Lukas
Mager, Magnus
Marras, Davide
Martinengo, Paolo
Masciocchi, Silvia
Menzel, Marius Wilm
Munker, Magdalena
Piro, Francesco
Rachevski, Alexandre
Rebane, Karoliina
Reidt, Felix
Russo, Roberto
Sanna, Isabella
Sarritzu, Valerio
Senyukov, Serhiy
Snoeys, Walter
Sonneveld, Jory
Šuljić, Miljenko
Svihra, Peter
Tiltmann, Nicolas
Usai, Gianluca
Van Beelen, Jacob Bastiaan
Vassilev, Mirella Dimitrova
Vernieri, Caterina
Villani, Anna
author_facet Rinella, Gianluca Aglieri
Andronic, Anton
Antonelli, Matias
Aresti, Mauro
Baccomi, Roberto
Becht, Pascal
Beole, Stefania
Braach, Justus
Buckland, Matthew Daniel
Buschmann, Eric
Camerini, Paolo
Carnesecchi, Francesca
Cecconi, Leonardo
Charbon, Edoardo
Contin, Giacomo
Dannheim, Dominik
de Melo, Joao
Deng, Wenjing
di Mauro, Antonello
Hasenbichler, Jan
Hillemanns, Hartmut
Hong, Geun Hee
Isakov, Artem
Junique, Antoine
Kluge, Alex
Kotliarov, Artem
Křížek, Filip
Lautner, Lukas
Mager, Magnus
Marras, Davide
Martinengo, Paolo
Masciocchi, Silvia
Menzel, Marius Wilm
Munker, Magdalena
Piro, Francesco
Rachevski, Alexandre
Rebane, Karoliina
Reidt, Felix
Russo, Roberto
Sanna, Isabella
Sarritzu, Valerio
Senyukov, Serhiy
Snoeys, Walter
Sonneveld, Jory
Šuljić, Miljenko
Svihra, Peter
Tiltmann, Nicolas
Usai, Gianluca
Van Beelen, Jacob Bastiaan
Vassilev, Mirella Dimitrova
Vernieri, Caterina
Villani, Anna
author_sort Rinella, Gianluca Aglieri
collection CERN
description The ALICE ITS3 (Inner Tracking System 3) upgrade project and the CERN EP R&D on monolithic pixel sensors are investigating the feasibility of the Tower Partners Semiconductor Co. 65nm process for use in the next generation of vertex detectors. The ITS3 aims to employ wafer-scale Monolithic Active Pixel Sensors thinned down to 20–40µm and bent to form truly cylindrical half barrels. Among the first critical steps towards the realisation of this detector is to validate the sensor technology through extensive characterisation both in the laboratory and with in-beam measurements. The Digital Pixel Test Structure (DPTS) is one of the prototypes produced in the first sensor submission in this technology and has undergone a systematic measurement campaign whose details are presented in this article. The results confirm the goals of detection efficiency and non-ionising and ionising radiation hardness up to the expected levels for ALICE ITS3 and also demonstrate operation at +20°C and a detection efficiency of 99% for a DPTS irradiated with a dose of 10<sup loc="post">15</sup>1MeV n<math altimg="si159.svg" display="inline" id="d1e1850"><mrow><mi>e</mi><mi>q</mi></mrow></math> cm<sup loc="post">-2</sup>. Furthermore, spatial, timing and energy resolutions were measured at various settings and irradiation levels.
id cern-2845385
institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2022
record_format invenio
spelling cern-28453852023-10-19T02:26:16Zdoi:10.1016/j.nima.2023.168589http://cds.cern.ch/record/2845385engRinella, Gianluca AglieriAndronic, AntonAntonelli, MatiasAresti, MauroBaccomi, RobertoBecht, PascalBeole, StefaniaBraach, JustusBuckland, Matthew DanielBuschmann, EricCamerini, PaoloCarnesecchi, FrancescaCecconi, LeonardoCharbon, EdoardoContin, GiacomoDannheim, Dominikde Melo, JoaoDeng, Wenjingdi Mauro, AntonelloHasenbichler, JanHillemanns, HartmutHong, Geun HeeIsakov, ArtemJunique, AntoineKluge, AlexKotliarov, ArtemKřížek, FilipLautner, LukasMager, MagnusMarras, DavideMartinengo, PaoloMasciocchi, SilviaMenzel, Marius WilmMunker, MagdalenaPiro, FrancescoRachevski, AlexandreRebane, KaroliinaReidt, FelixRusso, RobertoSanna, IsabellaSarritzu, ValerioSenyukov, SerhiySnoeys, WalterSonneveld, JoryŠuljić, MiljenkoSvihra, PeterTiltmann, NicolasUsai, GianlucaVan Beelen, Jacob BastiaanVassilev, Mirella DimitrovaVernieri, CaterinaVillani, AnnaDigital Pixel Test Structures implemented in a 65 nm CMOS processphysics.ins-detDetectors and Experimental TechniquesThe ALICE ITS3 (Inner Tracking System 3) upgrade project and the CERN EP R&D on monolithic pixel sensors are investigating the feasibility of the Tower Partners Semiconductor Co. 65nm process for use in the next generation of vertex detectors. The ITS3 aims to employ wafer-scale Monolithic Active Pixel Sensors thinned down to 20–40µm and bent to form truly cylindrical half barrels. Among the first critical steps towards the realisation of this detector is to validate the sensor technology through extensive characterisation both in the laboratory and with in-beam measurements. The Digital Pixel Test Structure (DPTS) is one of the prototypes produced in the first sensor submission in this technology and has undergone a systematic measurement campaign whose details are presented in this article. The results confirm the goals of detection efficiency and non-ionising and ionising radiation hardness up to the expected levels for ALICE ITS3 and also demonstrate operation at +20°C and a detection efficiency of 99% for a DPTS irradiated with a dose of 10<sup loc="post">15</sup>1MeV n<math altimg="si159.svg" display="inline" id="d1e1850"><mrow><mi>e</mi><mi>q</mi></mrow></math> cm<sup loc="post">-2</sup>. Furthermore, spatial, timing and energy resolutions were measured at various settings and irradiation levels.The ALICE ITS3 (Inner Tracking System 3) upgrade project and the CERN EP R&D on monolithic pixel sensors are investigating the feasibility of the Tower Partners Semiconductor Co. 65 nm process for use in the next generation of vertex detectors. The ITS3 aims to employ wafer-scale Monolithic Active Pixel Sensors thinned down to 20 to 40 um and bent to form truly cylindrical half barrels. Among the first critical steps towards the realisation of this detector is to validate the sensor technology through extensive characterisation both in the laboratory and with in-beam measurements. The Digital Pixel Test Structure (DPTS) is one of the prototypes produced in the first sensor submission in this technology and has undergone a systematic measurement campaign whose details are presented in this article. The results confirm the goals of detection efficiency and non-ionising and ionising radiation hardness up to the expected levels for ALICE ITS3 and also demonstrate operation at +20 C and a detection efficiency of 99% for a DPTS irradiated with a dose of $10^{15}$ 1 MeV n$_{\mathrm{eq}}/$cm$^2$. Furthermore, spatial, timing and energy resolutions were measured at various settings and irradiation levels.arXiv:2212.08621oai:cds.cern.ch:28453852022-12-16
spellingShingle physics.ins-det
Detectors and Experimental Techniques
Rinella, Gianluca Aglieri
Andronic, Anton
Antonelli, Matias
Aresti, Mauro
Baccomi, Roberto
Becht, Pascal
Beole, Stefania
Braach, Justus
Buckland, Matthew Daniel
Buschmann, Eric
Camerini, Paolo
Carnesecchi, Francesca
Cecconi, Leonardo
Charbon, Edoardo
Contin, Giacomo
Dannheim, Dominik
de Melo, Joao
Deng, Wenjing
di Mauro, Antonello
Hasenbichler, Jan
Hillemanns, Hartmut
Hong, Geun Hee
Isakov, Artem
Junique, Antoine
Kluge, Alex
Kotliarov, Artem
Křížek, Filip
Lautner, Lukas
Mager, Magnus
Marras, Davide
Martinengo, Paolo
Masciocchi, Silvia
Menzel, Marius Wilm
Munker, Magdalena
Piro, Francesco
Rachevski, Alexandre
Rebane, Karoliina
Reidt, Felix
Russo, Roberto
Sanna, Isabella
Sarritzu, Valerio
Senyukov, Serhiy
Snoeys, Walter
Sonneveld, Jory
Šuljić, Miljenko
Svihra, Peter
Tiltmann, Nicolas
Usai, Gianluca
Van Beelen, Jacob Bastiaan
Vassilev, Mirella Dimitrova
Vernieri, Caterina
Villani, Anna
Digital Pixel Test Structures implemented in a 65 nm CMOS process
title Digital Pixel Test Structures implemented in a 65 nm CMOS process
title_full Digital Pixel Test Structures implemented in a 65 nm CMOS process
title_fullStr Digital Pixel Test Structures implemented in a 65 nm CMOS process
title_full_unstemmed Digital Pixel Test Structures implemented in a 65 nm CMOS process
title_short Digital Pixel Test Structures implemented in a 65 nm CMOS process
title_sort digital pixel test structures implemented in a 65 nm cmos process
topic physics.ins-det
Detectors and Experimental Techniques
url https://dx.doi.org/10.1016/j.nima.2023.168589
http://cds.cern.ch/record/2845385
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