002673548 001__ 2673548
002673548 003__ SzGeCERN
002673548 005__ 20190508205304.0
002673548 0247_ $$2DOI$$9JACoW$$a10.18429/JACoW-SRF2017-TUXAA02
002673548 0248_ $$aoai:inspirehep.net:1669430$$pcerncds:CERN$$popenaire$$qcerncds:CERN:FULLTEXT$$qcerncds:FULLTEXT$$qINSPIRE:HEP$$qForCDS
002673548 035__ $$9http://inspirehep.net/oai2d$$aoai:inspirehep.net:1669430$$d2019-05-06T13:37:38Z$$h2019-05-07T04:00:10Z$$mmarcxml
002673548 035__ $$9Inspire$$a1669430
002673548 041__ $$aeng
002673548 100__ $$aVenturini Delsolaro, Walter$$jJACoW-00003806$$mwalter.venturini@cern.ch$$uCERN
002673548 245__ $$9JACoW$$aLessons learned from the HIE-Isolde cavity production and cryomodule commissioning
002673548 260__ $$c2018
002673548 300__ $$a7 p
002673548 520__ $$9JACoW$$aThe HIE-ISOLDE superconducting linac started opera- tions at CERN in 2015 with a first cryomodule hosting five superconducting quarter wave resonators (QWR). These cavities are based on the Nb/Cu technology. In time, two more cryomodules have been assembled, installed and commissioned on line, bringing the energy reach for the heaviest ions (A/q=4.5) up to 7.5 MeV/u. In 2017, while the first three cryomodules were prepared for the physics run, six more cavities were produced of which five will be installed in a fourth cryomodule. With this, the high beta section of the linac will be complete and the energy will reach 10 MeV/u for A/q=4.5. In this paper we review the experience and lessons learned during the construction of HIE-ISOLDE, along with some still open questions.
002673548 540__ $$aCC-BY-3.0$$bJACoW$$uhttp://creativecommons.org/licenses/by/3.0/
002673548 65017 $$2SzGeCERN$$aAccelerators and Storage Rings
002673548 6531_ $$2JACoW$$aion
002673548 6531_ $$2JACoW$$acavity
002673548 6531_ $$2JACoW$$aISOL
002673548 6531_ $$2JACoW$$acryomodule
002673548 6531_ $$2JACoW$$alinac
002673548 690C_ $$aCERN
002673548 693__ $$eCERN HIE ISOLDE
002673548 700__ $$aArtoos, Kurt$$jJACoW-00005883$$kORCID:0000-0003-1821-2426$$memail:kurt.artoos@cern.ch$$uCERN
002673548 700__ $$aCapatina, Ofelia$$jJACoW-00001541$$mofelia.capatina@cern.ch$$uCERN
002673548 700__ $$aDr Schirm, Karl-Martin$$jJACoW-00021377$$mkarl.schirm@cern.ch$$uCERN
002673548 700__ $$aKadi, Yacine$$jJACoW-00004380$$kORCID:0000-0001-5618-4644$$memail:yacine.kadi@cern.ch$$uCERN
002673548 700__ $$aLeclercq, Yann$$jJACoW-00049358$$myann.leclercq@cern.ch$$uCERN
002673548 700__ $$aMiyazaki, Akira$$jJACoW-00081891$$makira.miyazaki@cern.ch$$uCERN
002673548 700__ $$aMontesinos, Eric$$jJACoW-00019509$$meric.montesinos@cern.ch$$uCERN
002673548 700__ $$aParma, Vittorio$$jJACoW-00004464$$mvittorio.parma@cern.ch$$uCERN
002673548 700__ $$aRosaz, Guillaume$$jJACoW-00074653$$kORCID:0000-0001-5987-128X$$memail:guillaume.rosaz@cern.ch$$uCERN
002673548 700__ $$aSublet, Alban$$jJACoW-00064260$$malban.sublet@cern.ch$$uCERN
002673548 700__ $$aTeixeira Lopez, Silvia$$jJACoW-00092688$$msilvia.teixeira@cern.ch$$uCERN
002673548 700__ $$aTherasse, Mathieu$$jJACoW-00046578$$mmathieu.therasse@cern.ch$$uCERN
002673548 700__ $$aWilliams, Lloyd$$jJACoW-00021532$$mlloyd.ralph.williams@cern.ch$$uCERN
002673548 773__ $$cTUXAA02$$qSRF2017$$wC17-07-17.5$$y2018
002673548 8564_ $$81479325$$s1966513$$uhttps://cds.cern.ch/record/2673548/files/tuxaa02.pdf
002673548 960__ $$a13
002673548 962__ $$b2306019$$kTUXAA02$$nlanzhou20170717
002673548 980__ $$aARTICLE
002673548 980__ $$aConferencePaper
002673548 999C6 $$a0-0-0-1-0-0-1$$t2018-04-27 13:23:01$$vcontent.pdf;1$$vInvenio/1.1.2.1260-aa76f refextract/1.5.44
002673548 999C5 $$hM. Pasini et al.$$min Proc. LINAC’08, Victoria, BC, Canada$$o1$$tA SC upgrade for the REX-ISOLDE accelerator at CERN
002673548 999C5 $$o2$$uhttps://en.wikipedia.org/wiki/Matrix_management
002673548 999C5 $$o3$$uhttps://espace.cern.ch/Marie-Curie-CATHI
002673548 999C5 $$hV. Palmieri, V. L. Ruzinov, S. Stark, et al.$$min Proc. of the Sixth Workshop on RF Superconductivity (SRF’93), Newport News, Virginia$$o4$$tNew Results on Niobium sputtered Copper quarter wave resonators$$y1993
002673548 999C5 $$hL. Alberty et al.$$min Proc. SRF’13, Paris, France$$o5$$tThe copper substrate developments for the HIE-ISOLDE high beta quarter wave resonators
002673548 999C5 $$hS. Teixeira Lopez, M. A. Fraser, T. Mikkola, A. Myazaki, and W. Venturini Delsolaro$$mpresented at SRF’17, Lanzhou, China, paper WEYA03$$o6$$tA seamless Quarter-Wave Resonators for HIE-ISOLDE
002673548 999C5 $$hW. Venturini Delsolaro, S. Calatroni, B. Delaup, A. D’Elia, N. M. Jecklin, Y. Kadi, G. Keppel, D. Lespinasse, P. Maesen, I. Mondino, V. Palmieri, S. Stark, A. R. M. Sublet, and M. Therasse$$min Proc. SRF’13, Paris, France$$o7$$tNiobium Sputtered Quarter-Wave Resonators for HIE-ISOLDE
002673548 999C5 $$hA. Awais, A.J.G. Lunt, A. Sublet, G. Rosaz, and M. Taborelli$$mpresented at SRF’17, Lanzhou, China, paper THPB048$$o8$$tDouble cathode configuration for the niobium coating of HIE-ISOLDE cavities
002673548 999C5 $$hP. Zhang$$min Proc. SRF’15, Whistler, BC, Canada$$o9$$tThe multipacting study of niobium sputtered high beta quarter-wave resonators for HIE-ISOLDE
002673548 999C5 $$hH. Padamsee$$mRF superconductivity,, Whiley-VCH$$o10$$y2009
002673548 999C5 $$hP. Zhang, G. Rosaz, A. Sublet, and W. Venturini Delsolaro$$min Proc. SRF’15, Whistler, BC, Canada$$o11$$tThe Influence of Cooldown Conditions at Transition Temperature on the Quality Factor of Niobium Sputtered Quarter-Wave Resonators for HIE-ISOLDE
002673548 999C5 $$hA. Myazaki et al.$$mpresented at SRF’17, Lanzhou, China, paper WEXA06$$o12$$tThe Role of Cool Down Dynamics on the Performance on Nb/Cu Cavities
002673548 999C5 $$hW. Weingarten$$min Proc. of theWorkshop on RF Superconductivity, Gifsur-Yvette, France$$o13$$tProgress in Thin Film Techniques$$y1995
002673548 999C5 $$9CURATOR$$hP. Zhang, A. D’Elia, W. Venturini Delsolaro, and K. Artoos$$mNuclear Instruments and Methods in Physics Research, Section A vol. 797, October, pp. 101-109$$o14$$sNucl.Instrum.Meth.,A797,101$$tFrequency pre-tuning for the niobium sputtered quarterwave Resonators for HIE-ISOLDE project at CERN$$y2015
002673548 999C5 $$hM. Elias, D. Valuch$$mavailable on line:$$o15$$rCERN-THESIS-2013-165$$tDigital Measurement System for the HIE-Isolde Superconducting Accelerating Cavities$$uhttp://cds.cern.ch/record/1615604
002673548 999C5 $$hW. Venturini Delsolaro, E. Bravin, N. Delruelle, M. Elias, E. Fadakis, J.A. Ferreira, F. Formenti, M. A. Fraser, J.C. Gayde, N. Guillotin, Y. Kadi, G. Kautzmann, T. Koettig, Y. Leclercq, M. Martino, M. Mician, A. Miyazaki, E. Montesinos, V. Parma, J.A. Rodriguez, S. Sadovich, E. Siesling, D. Smekens, M. Therasse, L. Valdarno, D. Valuch, G. Vandoni, U. Wagner, and P. Zhang$$min Proc. LINAC’16, East Lansing, MI, USA$$o16$$tHIEISOLDE SC linac progress and commissioning in 2016
002673548 999C5 $$hL Williams, A. Bouzoud, N. Delruelle, J-C. Gayde, Y. Leclercq, M. Pasini, J-P. Tock, and G. Vandoni$$min Proc. IPAC’11, San Sebastian, Spain$$o17$$tDesign of the high beta cryomodule for the HIE ISOLDE upgrade at CERN
002673548 999C5 $$hY. Leclercq et al.$$min Proc. IPAC’15, Richmond, VA, USA$$o18$$tThe assembly experience of the first cryomodule for HIE-ISOLDE at CERN
002673548 999C5 $$9CURATOR$$mW. Venturini Delsolaro, E. Bravin, N. Delruelle, M. Elias, J.A. Ferreira, M.A. Fraser, J.C. Gayde, Y. Kadi, F. Klumb, G. Kautzmann, Y. Leclercq, M. Martino, V. Parma, J.A. Rodriguez, S. Sadovich, D. Smekens, E. Siesling, L. Valdarno, D. Valuch, and P. Zhang, “HIE-ISOLDE” first commissioning experience”, in Proc. IPAC’16, Busan, Korea.$$o19