002712241 001__ 2712241
002712241 003__ SzGeCERN
002712241 005__ 20200312105931.0
002712241 0247_ $$2DOI$$9Elsevier$$a10.1016/j.nima.2019.04.042
002712241 0248_ $$aoai:inspirehep.net:1782857$$pcerncds:CERN$$qINSPIRE:HEP$$qForCDS
002712241 035__ $$9http://inspirehep.net/oai2d$$aoai:inspirehep.net:1782857$$d2020-03-05T14:53:33Z$$h2020-03-06T07:57:31Z$$mmarcxml
002712241 035__ $$9Inspire$$a1782857
002712241 041__ $$aeng
002712241 100__ $$aAly, R$$uBari Polytechnic$$uINFN, Bari$$vINFN, Bari, Italy
002712241 245__ $$9Elsevier$$aFirst test-beam results obtained with IDEA, a detector concept designed for future lepton colliders
002712241 260__ $$bElsevier$$c2020
002712241 300__ $$a4 p
002712241 520__ $$9Elsevier$$aIDEA (Innovative Detector for Electron–positron Accelerators) is a detector concept designed for a future leptonic collider operating as a Higgs factory. It is based on innovative detector technologies developed over years of R&D.; In September 2018, prototypes of the proposed sub-detectors have been tested for the first time on a beam line at CERN. The preliminary results from this test of a full slice of the IDEA detector and standalone measurements of dual read-out calorimeter prototypes are presented.
002712241 542__ $$3Publication$$fElsevier B.V.$$g2019
002712241 65017 $$2SzGeCERN$$aDetectors and Experimental Techniques
002712241 6531_ $$9author$$aIDEA
002712241 6531_ $$9author$$aDual-readout calorimeter
002712241 6531_ $$9author$$aMPGD
002712241 6531_ $$9author$$aμ -RWELL
002712241 6531_ $$9author$$aGEM
002712241 6531_ $$9author$$aDrift-chamber
002712241 6531_ $$9author$$aTest-beam
002712241 6531_ $$9author$$aGas detectors
002712241 6531_ $$9author$$a[formula omitted]-RWELL
002712241 690C_ $$aCERN
002712241 700__ $$aAntonello, M$$uInsubria U., Como$$uINFN, Milan$$vINFN, Milano, Italy
002712241 700__ $$aAzzi, P$$uINFN, Padua
002712241 700__ $$aBedeschi, F$$uPisa U.$$uINFN, Pisa$$vINFN, Pisa, Italy
002712241 700__ $$aBencivenni, G$$uFrascati
002712241 700__ $$aBorgonovi, [email protected]$$uU. Bologna (main)$$uINFN, Bologna$$vINFN, Bologna, Italy
002712241 700__ $$aCaccia, M L M$$uInsubria U., Como$$uINFN, Milan$$vINFN, Milano, Italy
002712241 700__ $$aChu, X$$uICTS, Beijing
002712241 700__ $$aCibinetto, G$$uINFN, Ferrara
002712241 700__ $$aCoates, T$$uSussex U.
002712241 700__ $$aCussans, D$$uBristol U.
002712241 700__ $$aDe Filippis, N$$uBari Polytechnic$$uINFN, Bari$$vINFN, Bari, Italy
002712241 700__ $$aDe Santo, A$$uSussex U.
002712241 700__ $$aDunser, M$$uCERN
002712241 700__ $$aEte, R$$uDESY
002712241 700__ $$aFarinelli, R$$uFerrara U.$$uINFN, Ferrara$$vINFN, Ferrara, Italy
002712241 700__ $$aFerrari, R$$uINFN, Pavia
002712241 700__ $$aFontanesi, E$$uU. Bologna (main)$$uINFN, Bologna$$vINFN, Bologna, Italy
002712241 700__ $$aFranchino, S$$uKirchhoff Inst. Phys.
002712241 700__ $$aGaudio, G$$uINFN, Pavia
002712241 700__ $$aGiacomelli, P$$uINFN, Bologna
002712241 700__ $$aGrancagnolo, F$$uSalento U.$$uINFN, Lecce$$vINFN, Lecce, Italy
002712241 700__ $$aGribanov, S$$uNovosibirsk, IYF
002712241 700__ $$aHauptman, J M$$uIowa State U.
002712241 700__ $$aJanot, P$$uCERN
002712241 700__ $$aJones, S D$$uSussex U.
002712241 700__ $$aLee, K$$uDMRC, Seoul
002712241 700__ $$aLee, S$$uKyungpook Natl. U.
002712241 700__ $$aLerner, G$$uCERN
002712241 700__ $$aMorello, G$$uFrascati
002712241 700__ $$aNam, K$$uDMRC, Seoul
002712241 700__ $$aPezzotti, L$$uPavia U.$$uINFN, Pavia$$vINFN, Pavia, Italy
002712241 700__ $$aPingault, A$$uGent U.
002712241 700__ $$aLener, M Poli$$uFrascati
002712241 700__ $$aPopov, A A$$uNovosibirsk, IYF
002712241 700__ $$aSalvatore, F$$uSussex U.
002712241 700__ $$aSantoro, R$$uInsubria U., Como$$uINFN, Milan$$vINFN, Milano, Italy
002712241 700__ $$aTaliercio, A$$uBari Polytechnic$$uINFN, Bari$$vINFN, Bari, Italy
002712241 700__ $$aTassielli, G F$$uSalento U.$$uINFN, Lecce$$vINFN, Lecce, Italy
002712241 700__ $$aTesta, B$$uSalento U.$$uINFN, Lecce$$vINFN, Lecce, Italy
002712241 700__ $$aVivarelli, I$$uSussex U.
002712241 700__ $$aWigmans, R$$uTexas Tech.
002712241 710__ $$gINFN RD-FA
002712241 773__ $$01782753$$c162088$$pNucl. Instrum. Methods Phys. Res., A$$v958$$wC19-02-18$$y2020
002712241 960__ $$a13
002712241 962__ $$b2655927$$k162088$$nvienna20190218
002712241 980__ $$aARTICLE
002712241 980__ $$aConferencePaper
002712241 999C5 $$01713705$$hBenedikt, M.$$mFuture Circular Collider Study, Volume 2: The Lepton Collider (FCC-ee) Conceptual Design Report, preprint CERN accelerator reports$$o1$$rCERN-ACC-2018-0057$$z0
002712241 999C5 $$01705023$$marXiv:1811.10545$$o2$$rarXiv:1811.10545$$tCEPC conceptual design report: Volume 2 - physics & detector$$y2018$$z0
002712241 999C5 $$hChiarello, G.$$o3$$sJ.Instum.,12,C03062$$tThe full stereo drift chamber for the MEG II experiment$$y2017$$z0
002712241 999C5 $$01520803$$hSauli, F.$$o4$$sNucl.Instrum.Meth.,A805,2$$tThe gas electron multiplier (GEM): Operating principles and applications$$y2016$$z0
002712241 999C5 $$01643641$$hLee, S.$$hLivan, M.$$hWigmans, R.$$o5$$sRev.Mod.Phys.,90,025002$$tDual-readout calorimetry$$y2018$$z0
002712241 999C5 $$01519427$$hLee, S.$$o6$$sNucl.Instrum.Meth.,A866,76$$tHadron detection with a dual-readout fiber calorimeter$$y2017$$z0
002712241 999C5 $$01326914$$hBencivenni, G.$$o7$$sJINST,10,P02008$$tThe micro-Resistive WELL detector: A compact spark-protected single amplification-stage MPGD$$y2015$$z0
002712241 999C5 $$01672363$$hAntonello, M.$$o8$$sNucl.Instrum.Meth.,A899,52$$tTests of a dual-readout fibre calorimeter with SiPM light sensors$$y2018$$z0
002712241 999C5 $$01741713$$adoi:10.1016/j.nima.2018.10.169$$hAntonello, M.$$mNucl.Instrum.Meth.,A$$o9$$tDevelopment of a Silicon Photomultiplier based dual readout calorimeter: The pathway beyond the proof-of-concept$$y2018$$z0