002912733 001__ 2912733
002912733 003__ SzGeCERN
002912733 005__ 20241008234244.0
002912733 0247_ $$2DOI$$9Elsevier B.V.$$a10.1016/j.nima.2024.169831$$qpublication
002912733 0248_ $$aoai:cds.cern.ch:2912733$$pcerncds:FULLTEXT$$pcerncds:CERN:FULLTEXT$$pcerncds:CERN
002912733 035__ $$9https://inspirehep.net/api/oai2d$$aoai:inspirehep.net:2832171$$d2024-10-07T11:33:23Z$$h2024-10-08T04:00:09Z$$mmarcxml
002912733 035__ $$9Inspire$$a2832171
002912733 041__ $$aeng
002912733 100__ $$aAlì, M$$uINFN, Bologna
002912733 245__ $$9Elsevier B.V.$$aThe μ-RWELL technology for tracking apparatus in High Energy Physics
002912733 260__ $$c2024
002912733 300__ $$a3 p
002912733 520__ $$9Elsevier B.V.$$aThe micro-Resitive WELL (μ-RWELL) is a Micro Pattern Gas Detector (MPGD) that inherits some of the best characteristics of existing MPGDs, like GEMs and MicroMegas, while simplifying the detector construction. A significant progress towards large-scale applications has been achieved through the consolidation and industrial cost-effective manufacturing of this technology. The μ-RWELL, showing excellent spatial performance, good time resolution and stability under irradiation, is proposed for several tracking apparatus for future experiments at future accelerators such as FCC (CERN), CEPC (China) and EIC (Brookhaven National Laboratory). The reduced impact in terms of material budget makes this technology suitable for the development of tracking devices in the muon spectrometer. In addition, the flexibility of the μ-RWELL base material makes this device suitable for the development of very light, fully cylindrical inner trackers at future high luminosity tau-charm factories, SCTF (China). We report in this paper some results in the development of 2D readouts for IDEA apparatus and the construction steps of a cylindrical μ-RWELL.
002912733 540__ $$3publication$$aCC BY-NC-ND 4.0$$uhttp://creativecommons.org/licenses/by-nc-nd/4.0/
002912733 542__ $$3publication$$dThe Author(s)$$g2024
002912733 65017 $$2SzGeCERN$$aDetectors and Experimental Techniques
002912733 6531_ $$9Elsevier B.V.$$aGaseous detectors
002912733 6531_ $$9Elsevier B.V.$$aMicro-pattern gaseous detectors
002912733 6531_ $$9Elsevier B.V.$$aTrackers
002912733 690C_ $$aARTICLE
002912733 690C_ $$aCERN
002912733 700__ $$aBencivenni, G$$uFrascati
002912733 700__ $$aBondì, M$$uINFN, Catania
002912733 700__ $$aCerioni, S$$uFrascati
002912733 700__ $$aCibinetto, G$$uINFN, Ferrara
002912733 700__ $$aD'Angelo, A$$uINFN, Rome2
002912733 700__ $$aDe Lucia, E$$uFrascati
002912733 700__ $$aDe Oliveira, R$$uCERN
002912733 700__ $$aDi Bari, D$$uFrascati
002912733 700__ $$aFarinelli, R$$uINFN, Ferrara
002912733 700__ $$aFelici, G$$uFrascati
002912733 700__ $$aGatta, M$$uFrascati
002912733 700__ $$aGiacomelli, P$$uINFN, Bologna
002912733 700__ $$aGiovannetti, M$$uFrascati
002912733 700__ $$aGramigna, S$$uINFN, Ferrara
002912733 700__ $$aMelchiorri, M$$uINFN, Ferrara
002912733 700__ $$aMelendi, F M$$uINFN, Ferrara
002912733 700__ $$aMorello, G$$mgianfranco.morello@lnf.infn.it$$uFrascati
002912733 700__ $$aLavezzi, L$$uTurin U.
002912733 700__ $$aPaoletti, E$$uFrascati
002912733 700__ $$aPapalino, G$$uFrascati
002912733 700__ $$aPoli Lener, M$$uFrascati
002912733 700__ $$aSidoretti, E$$uINFN, Rome2
002912733 700__ $$aTesauro, R$$uFrascati
002912733 773__ $$c169831$$mpublication$$pNucl. Instrum. Methods Phys. Res., A$$v1069$$wC24-05-26$$y2024
002912733 8564_ $$82562680$$s1274492$$uhttp://cds.cern.ch/record/2912733/files/Publication.pdf$$yFulltext
002912733 960__ $$a13
002912733 962__ $$b2896953$$k169831$$nla biodola, isola d'elba20240526
002912733 980__ $$aARTICLE
002912733 980__ $$aConferencePaper