Cargando…
Performance of CMOS pixel sensor prototypes in ams H35 and aH18 technology for the ATLAS ITk upgrade
Pixel sensors based on commercial high-voltage CMOS processes are an exciting technology that is considered as an option for the outer layer of the ATLAS inner tracker upgrade at the High Luminosity LHC. Here, charged particles are detected using deep n-wells as sensor diodes with the depleted regio...
| Autores principales: | , , , , , , , , , , , , , , , , , , , , , , , , , , , , , |
|---|---|
| Lenguaje: | eng |
| Publicado: |
2018
|
| Materias: | |
| Acceso en línea: | https://dx.doi.org/10.1016/j.nima.2018.07.061 http://cds.cern.ch/record/2635923 |
| _version_ | 1780959849205465088 |
|---|---|
| author | Kiehn, Moritz Di Bello, Francesco Armando Benoit, Mathieu Casanova Mohr, Raimon Chen, Hucheng Chen, Kai D.M.S., Sultan Ehrler, Felix Ferrere, Didier Frizell, Dylan Gonzalez Sevilla, Sergio Iacobucci, Giuseppe Lanni, Francesco Liu, Hongbin Merlassino, Claudia Metcalfe, Jessica Miucci, Antonio Peric, Ivan Prathapan, Mridula Schimassek, Rudolf Barreto, Mateus Vicente Weston, Thomas Figueras, Eva Vilella Weber, Alena Weber, Michele Wong, Winnie Wu, Weihao Zaffaroni, Ettore Zhang, Hui Zhang, Matt |
| author_facet | Kiehn, Moritz Di Bello, Francesco Armando Benoit, Mathieu Casanova Mohr, Raimon Chen, Hucheng Chen, Kai D.M.S., Sultan Ehrler, Felix Ferrere, Didier Frizell, Dylan Gonzalez Sevilla, Sergio Iacobucci, Giuseppe Lanni, Francesco Liu, Hongbin Merlassino, Claudia Metcalfe, Jessica Miucci, Antonio Peric, Ivan Prathapan, Mridula Schimassek, Rudolf Barreto, Mateus Vicente Weston, Thomas Figueras, Eva Vilella Weber, Alena Weber, Michele Wong, Winnie Wu, Weihao Zaffaroni, Ettore Zhang, Hui Zhang, Matt |
| author_sort | Kiehn, Moritz |
| collection | CERN |
| description | Pixel sensors based on commercial high-voltage CMOS processes are an exciting technology that is considered as an option for the outer layer of the ATLAS inner tracker upgrade at the High Luminosity LHC. Here, charged particles are detected using deep n-wells as sensor diodes with the depleted region extending into the silicon bulk. Both analog and digital readout electronics can be added to achieve different levels of integration up to a fully monolithic sensor. Small scale prototypes using the ams CMOS technology have previously demonstrated that it can achieve the required radiation tolerance of 10 15 n eq /cm 2 and detection efficiencies above 99.5%. Recently, large area prototypes, comparable in size to a full sensor, have been produced that include most features required towards a final design: the H35demo prototype produced in ams H35 technology that supports both external and integrated readout and the monolithic ATLASPix1 pre-production design produced in ams aH18 technology. Both chips are based on large fill-factor pixel designs, but differ in readout structure. Performance results for H35DEMO with capacitively-coupled external readout and first results for the monolithic ATLASPix1 are shown. |
| id | cern-2635923 |
| institution | Organización Europea para la Investigación Nuclear |
| language | eng |
| publishDate | 2018 |
| record_format | invenio |
| spelling | cern-26359232021-08-13T02:03:33Zdoi:10.1016/j.nima.2018.07.061http://cds.cern.ch/record/2635923engKiehn, MoritzDi Bello, Francesco ArmandoBenoit, MathieuCasanova Mohr, RaimonChen, HuchengChen, KaiD.M.S., SultanEhrler, FelixFerrere, DidierFrizell, DylanGonzalez Sevilla, SergioIacobucci, GiuseppeLanni, FrancescoLiu, HongbinMerlassino, ClaudiaMetcalfe, JessicaMiucci, AntonioPeric, IvanPrathapan, MridulaSchimassek, RudolfBarreto, Mateus VicenteWeston, ThomasFigueras, Eva VilellaWeber, AlenaWeber, MicheleWong, WinnieWu, WeihaoZaffaroni, EttoreZhang, HuiZhang, MattPerformance of CMOS pixel sensor prototypes in ams H35 and aH18 technology for the ATLAS ITk upgradephysics.ins-detDetectors and Experimental TechniquesPixel sensors based on commercial high-voltage CMOS processes are an exciting technology that is considered as an option for the outer layer of the ATLAS inner tracker upgrade at the High Luminosity LHC. Here, charged particles are detected using deep n-wells as sensor diodes with the depleted region extending into the silicon bulk. Both analog and digital readout electronics can be added to achieve different levels of integration up to a fully monolithic sensor. Small scale prototypes using the ams CMOS technology have previously demonstrated that it can achieve the required radiation tolerance of 10 15 n eq /cm 2 and detection efficiencies above 99.5%. Recently, large area prototypes, comparable in size to a full sensor, have been produced that include most features required towards a final design: the H35demo prototype produced in ams H35 technology that supports both external and integrated readout and the monolithic ATLASPix1 pre-production design produced in ams aH18 technology. Both chips are based on large fill-factor pixel designs, but differ in readout structure. Performance results for H35DEMO with capacitively-coupled external readout and first results for the monolithic ATLASPix1 are shown.Pixel sensors based on commercial high-voltage CMOS processes are an exciting technology that is considered as an option for the outer layer of the ATLAS inner tracker upgrade at the High Luminosity LHC. Here, charged particles are detected using deep n-wells as sensor diodes with the depleted region extending into the silicon bulk. Both analog and digital readout electronics can be added to achieve different levels of integration up to a fully monolithic sensor. Small scale prototypes using the ams CMOS technology have previously demonstrated that it can achieve the required radiation tolerance of $10^{15}~\text{n}_\text{eq}/\text{cm}^2$ and detection efficiencies above $99.5~\%$. Recently, large area prototypes, comparable in size to a full sensor, have been produced that include most features required towards a final design: the H35demo prototype produced in ams H35 technology that supports both external and integrated readout and the monolithic ATLASPix1 pre-production design produced in ams aH18 technology. Both chips are based on large fill-factor pixel designs, but differ in readout structure. Performance results for H35DEMO with capacitively-coupled external readout and first results for the monolithic ATLASPix1 are shown.arXiv:1807.05953oai:cds.cern.ch:26359232018-07-16 |
| spellingShingle | physics.ins-det Detectors and Experimental Techniques Kiehn, Moritz Di Bello, Francesco Armando Benoit, Mathieu Casanova Mohr, Raimon Chen, Hucheng Chen, Kai D.M.S., Sultan Ehrler, Felix Ferrere, Didier Frizell, Dylan Gonzalez Sevilla, Sergio Iacobucci, Giuseppe Lanni, Francesco Liu, Hongbin Merlassino, Claudia Metcalfe, Jessica Miucci, Antonio Peric, Ivan Prathapan, Mridula Schimassek, Rudolf Barreto, Mateus Vicente Weston, Thomas Figueras, Eva Vilella Weber, Alena Weber, Michele Wong, Winnie Wu, Weihao Zaffaroni, Ettore Zhang, Hui Zhang, Matt Performance of CMOS pixel sensor prototypes in ams H35 and aH18 technology for the ATLAS ITk upgrade |
| title | Performance of CMOS pixel sensor prototypes in ams H35 and aH18 technology for the ATLAS ITk upgrade |
| title_full | Performance of CMOS pixel sensor prototypes in ams H35 and aH18 technology for the ATLAS ITk upgrade |
| title_fullStr | Performance of CMOS pixel sensor prototypes in ams H35 and aH18 technology for the ATLAS ITk upgrade |
| title_full_unstemmed | Performance of CMOS pixel sensor prototypes in ams H35 and aH18 technology for the ATLAS ITk upgrade |
| title_short | Performance of CMOS pixel sensor prototypes in ams H35 and aH18 technology for the ATLAS ITk upgrade |
| title_sort | performance of cmos pixel sensor prototypes in ams h35 and ah18 technology for the atlas itk upgrade |
| topic | physics.ins-det Detectors and Experimental Techniques |
| url | https://dx.doi.org/10.1016/j.nima.2018.07.061 http://cds.cern.ch/record/2635923 |
| work_keys_str_mv | AT kiehnmoritz performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT dibellofrancescoarmando performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT benoitmathieu performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT casanovamohrraimon performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT chenhucheng performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT chenkai performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT dmssultan performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT ehrlerfelix performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT ferreredidier performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT frizelldylan performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT gonzalezsevillasergio performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT iacobuccigiuseppe performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT lannifrancesco performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT liuhongbin performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT merlassinoclaudia performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT metcalfejessica performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT miucciantonio performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT pericivan performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT prathapanmridula performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT schimassekrudolf performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT barretomateusvicente performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT westonthomas performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT figuerasevavilella performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT weberalena performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT webermichele performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT wongwinnie performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT wuweihao performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT zaffaroniettore performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT zhanghui performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade AT zhangmatt performanceofcmospixelsensorprototypesinamsh35andah18technologyfortheatlasitkupgrade |