CERN–2009–01 CARE–Conf–08–029–HHH 19January2009 ORGANISATION EUROP(cid:131)ENNE POUR LA RECHERCHE NUCL(cid:131)AIRE CERN EUROPEAN ORGANIZATION FOR NUCLEAR RESEARCH WAMSDO Workshop Accelerator magnet superconductors, design and optimization CERN, Geneva, Switzerland, 19–23 May 2008 Proceedings Editor: E. Todesco GENEVA 2009 CERN–300copiesprinted–January2009 Abstract This report contains the proceedings of the CARE-HHH-AMT Workshop on Accelerator Magnet Supercon- ductors,DesignandOptimization(WAMSDO)heldatCERNfrom19to23May2008. Theneedsintermsof superconducting magnets for the accelerator projects were discussed, mainly for the LHC interaction regions andinjectorupgrades, andfortheGSIFAIRcomplex. Thefirstpartoftheworkshopfocusedonthedevelop- mentofsuperconductorandcables,i.e.,low-lossNb-Ticables,Nb Snandhigh-temperaturesuperconductors. 3 An industry session summarized the actual plans and status of the activities in the main European industries. Then, a worldwide status of the high field magnets programme was presented. A special session was devoted to fast cycled magnets, including FAIR facilities and LHC injector upgrades. A final session focused on the optimizationmethodsandnumericaltoolsformagnetdesign. iii Preface Thescience(or, asmany wouldsay, theart)ofsuperconductingmagnetsfor accelerators reliesonknowl- edgeofseveraldifferentfields,suchaselectromagnetism,mechanicsandmaterialscience. Thisisthethirdand last of the workshops on magnet design organized in the framework of the European Programme FP6 by the CARE-HHHnetwork. Thefirstworkshop,WAMS,wasmorefocusedonsuperconductors,andthesecondone, WAMDO, rather on magnet design and optimization. In this third workshop we include aspects concerning both magnet design and superconductor development, to describe the present status and to draw perspectives forfutureR&Dactivities. Magnetrequirements The opening session of the workshop was devoted to the magnet requirements coming from current or future projects. The possibilities for a LHC luminosity upgrade have been studied for several years, requiring the difficult task of identifying the LHC luminosity bottlenecks before having the first collisions. The unanimous opinion is that the present 70 mm aperture of the interaction region quadrupoles is too small, and that larger- aperturequadrupolesareneeded. Theupgradehasrecentlybeensplitintotwophases: thefirstone,scheduled for2013,requires120mmaperture10-m-longquadrupolesinNb-Ti(seethecontributionofR.Ostojic,p. 1). Thisfirstphaseaimsatanincreaseofafactor2.5withrespecttonominalluminosity,i.e.,2.5 1034cm 2s 1. − − × Half of this increase would come from the stronger focusing (β = 0.25 m instead of 0.55 m) allowed by the ∗ larger-aperturequadrupoles,andtheotherhalffromanincreaseofthebunchintensity. Asecondphasewould pushthefocusingtothelimitgivenbytheNb Sntechnology,i.e.,β = 0.15m,throughquadrupoleswithan 3 ∗ even larger aperture of 130–150 mm. This quadrupole aperture is somewhat larger than the original proposal made by the U.S. LHC Accelerator Research Program (LARP), which considered 90 mm aperture magnets. Today several 90 mm aperture models are being built, successfully validating the technology, and a 120 mm aperturequadrupole,whichcouldbeusedasaspareforPhaseI,isinthedesignphase. The upgrade of the chain of the LHC injectors has also been the object of a long series of studies: today, LINAC4hasjuststartedthecivilengineeringworksandaconceptualdesignforthePSupgrade(PS2)isbeing finalized. EventhoughthepresentbaselineforthePS2considersnormalconductingmagnets,asuperferricop- tionisstillonthetable. ThisoptioncouldalsobeinterestingforafutureupgradeoftheSPS.Thisrequirement ofrelativelylowfield(2–4T),fastcyclingmagnetsalsocomesfromtheconstructionofSIS100andSIS300 inGSI,Darmstadt. Bothasuperferricoptionandastandardcosθ designwithlowlossesarebeingconsidered. These magnets could offer a reliable and more environmentally friendly alternative to the normal conducting technology. Inordertotestcablesusedforsuperconductingmagnets, oneneedsabackgroundmagneticfieldwhichis usually generated by solenoids and/or dipoles. These magnets used in test facilities need a large aperture to house the samples. At CERN, a replacement of the FRESCA facility with a 100 mm aperture dipole in the rangeof13–15T,makinguseoftheNEDcable,isunderstudy. For a linear collider such as the ILC or CLIC, a large set of superconducting magnets is foreseen (see the slidesofM.Tartagliaavailableontheconferencewebsitehttp://indico.cern.ch/conferenceDisplay. py?confId=28832): forexample,theforeseenILChardwarezooincludesquadrupoles,steeringdipoles,wig- glers and undulators; in most cases the chosen option is the superferric one. Future projects such as muon collidersorneutrinofactoriespresentthechallengingfeatureofhavingalargeradiationloadinthebeammid- plane: thiscouldrequireinnovativesolutionsforthemagnetdesignsuchastheopenmid-planeoption,strongly supported by R. Gupta in recent years. The Farthest Energy Frontier (FEF) which is conceivable today with presenttechnology,infrastructureandcostslimitationsistheLHCdoubler(seetheslidesofL.Evansavailable v ontheconferencewebsitehttp://indico.cern.ch/conferenceDisplay.py?confId=28832). Thisnew machine,makinguseofmostoftheLHCinfrastructure,wouldrequire15TdipolesinNb Snwithanaperture 3 ofabout40mm. TheLBNLmodelHD2,recentlytested,hasparameterswhichfallinthisrange. ThefirstresultsfromLHCphysicswillbeanextremelyimportantpieceofinformationtohelpunderstand wheretogo. Materials,strandsandcables The research on superconductors is focused on several issues. For the Nb-Ti, which has been the workhorse for accelerator magnets for 30 years, the main research line aims at low-loss cables for fast cycling magnets. Thetopicoflossesinsuperconductingfastcyclingmagnetsisstillfarfrombeingclosed,boththeoreticallyand from a manufacturing point of view. The main challenge is to find a strand layout that can minimize losses, achievethenecessaryJ ,andthatcanbemanufactured. Gettingastrandwiththinnerandthinnerfilamentsize c is not the only issue: considerations about the transverse resistivity, the geometry of the cable, and the design ofthewholemagnetarealsorelevant(seethecontributionsbyM.N.Wilson,G.Volpini,U.Gambardella,and V.Pantsyrny,pp. 8–23). Anextensionoftheworkonlow-losscablestoNb SnwaspresentedbyT.Collings, 3 p. 42. Nb SnhasforalongtimebeenconsideredasthenaturalsuccessorofNb-Ti,allowingtoroughlydoublethe 3 fieldfrom8–10Tto15–20T,inthesamerangeoftemperatures(1.9–4.2K).Theprogressinthedevelopment of Nb Sn cables towards larger critical currents has been impressive: in the past ten years the current density 3 inthenon-copperparthasdoubled(seetheA.GodekeandT.Boutboulcontributions,pp. 24–29). Atthesame time, recent analyses show that very large critical current densities can produce self-field instabilities limiting theperformances(seethecontributionbyB.Bordini,p. 51);thisanalysisaccountsforthereducedperformance of LARP quadrupoles at 1.9 K. This could be the sign that the quest for larger and larger current densities at 12–15Thasreacheditsnaturallimit,orthat,ifonewantstostillpursuethisdirection,newparametershaveto betakenintoaccountinthecabledesign. One of the main issues of Nb Sn is its sensitivity to strain. Several techniques can be used to study this 3 complex issue and many other characteristics, related both to the strand layout and to the magnet design and optimization. Metallographic techniques, calorimetric analysis, synchrotron radiation, and measurements of critical current under strain have been used for Nb Sn strands for the ITER and for the NED projects (see 3 contributionsbyM.Jewell,C.Scheuerlein,andB.Seeberpp. 30–41). A special cable layout used for fusion projects such as ITER is the so-called cable-in-conduit, aiming at higher current and having a more efficient cooling with respect to the Rutherford cable used for accelerator magnets. AfullreviewoftheperformanceofbothNb-TiandNb Sncable-in-conduitusedinITERisgivenin 3 thecontributionofR.Wesche,p. 68. For accelerator magnets, and even more for fusion magnets, the issue of radiation resistance is critical. A complete overview of the radiation resistance of Nb-Ti and Nb Sn, focused on a particle spectrum relative 3 to the debris of the collision in the LHC upgrade, can be found in the contribution by R. Flu¨kiger, p. 55. With the present knowledge of radiation loads, both Nb-Ti and Nb Sn should not suffer from a degradation 3 of performance over the expected lifetime of the magnets. The limitation to the magnet lifetime would rather comefromothermaterialssuchastheplasticusedforendspacersortheepoxyusedforNb Snimpregnation. 3 Newsuperconductorsarediscoveredeveryyear,andsomematerialshaveshownimpressiveprogress. This isthecaseofMgB ,amaterialwhichwasdiscoveredin2001,whosefieldrangeis2–4Tat20Kand5–10T 2 at 4.2 K. The current industrial developments aiming at having long cables with large current densities are described in the contributions of G. Grasso and G. Giunchi, pp. 78–88. High-temperature superconductors have been used for power lines and current leads in the LHC. The current state-of-the-art of HTS materials, mainlyBi-2212andYBaCuO,andtheirapplications,isgiveninthecontributionsofP.TixadorandofM.Noe, pp.89–97. vi High-fieldmagnets The results on high-field magnets constitute the core of these proceedings. The present design for the Nb-Ti upgradeoftheLHCinteractionquadrupolesispresentedbyP.Fessia,p. 101. Threedifferentprojectsaimingat constructingaccelerator-qualityNb SnmagnetsareunderwayintheU.S.TheLARPcollaborationisbuilding 3 large-aperture quadrupoles for the LHC interaction region upgrade, including several short models to test two mechanical structures, and a 3.4-m-long model, see the contributions of P. Ferracin, P. Wanderer, S. Caspi, and H. Felice, pp. 105–122. FNAL is developing high-field long dipoles, and LBNL has built and tested a short dipole based on a block coil and a bladder and keys structure, reaching a bore field of 13.5 T, see the contributionofP.Ferracin,p.105. Europe, mainly busy during the past ten years with LHC construction, started the NED programme in 2004 to develop a Nb Sn conductor within European industry. The programme is now successfully ending: 3 a new initiative has been financed by the EU to build a large-aperture dipole of 13 T with a large aperture to upgradethecableteststationatCERN,seethecontributionofG.DeRijk,p. 128. InCEA-Saclay,theNb Sn 3 programmeaimingatbuildinganLHC-likequadrupolewithNb Sncoilsisslowlybutsteadilyprogressing: the 3 finalmagnettestshouldbecarriedoutin2008(seethecontributionofJ.M.Rifflet,p. 131). Japanisexploring the possibility of building accelerator magnets with Nb Al, a conductor whose critical surface is not far from 3 Nb Snbutwhichhasanegligibledegradationduetostrain(seethecontributionofK.Sasaki,p. 132). 3 Othermagnetprojects To break the barrier of 20 T one needs to go to high-temperature superconductors. Today, these materials have been used to construct high-field solenoids; the present state-of-the-art is given in the contribution by D.Larbalestier,p.136. A recent project which is in the final stage, and will be commissioned in the next months, is the JPARC facilityforneutrinophysics. Itmakesuseofcombined-functionsuperconductingmagnets,whichareafirstin termsofmagnetdesign. Thisoptionisofgreatinterestforallmachineswherecompactnessisarelevantissue. Fastcycledmagnets In the past, low-energy machines have always made use of normal conducting magnets. Indeed, during the past years the GSI laboratory has chosen a superconductive technology for a low-energy machine, and su- perferric or superconductive options are being considered for several machines, including the LHC injectors. Thepossibilityofhavingbeamtransferlinesmadewithsuperferricmagnetsisexploredinthecontributionof H.Piekarz,p.142,includingboththeLTSandtheHTSoptions. Thesuperferricmagnetsthatwillbeusedfor theSIS100arepresentedbyE.Fischer,p. 147. TheDiscorapproject,aimingatbuildingalow-losscosθcurved dipoleinthe4TrangefortheSIS300facilityispresentedinthecontributionsbyP.FabbricatoreandM.Sorbi, pp.157–162. Magnetdesignoptimizationandtest Magnet design relies on the use of several codes for computing and optimizing the electromagnetic layout, mechanicalstructure, losses, andprotection. TheRoxiecode, whichhastakenanimportantplaceinthecom- munityofacceleratormagnetdesigners,hasrecentlyincludedquenchanalysis. Anoutlineofthenewfeatures andofthefuturedevelopmentsisgivenbyB.Auchmann,p. 163. Ontheotherhand,inthephaseofconceptual designitcanbeusefultohavealsoanalyticalorsemi-analyticalapproachesforafastexplorationoftheparam- eterspace. Asummaryofsemi-analyticalestimatesfortheshortsamplelimit, Lorentzstresses, andmagnetic energy as a function of the main coil parameters is given by E. Todesco, p. 168. The state-of-the-art of the magneticmeasurementsatCERNisgivenbyM.Buzio, p.172. ThetwofinalpapersbySchnizeraredevoted tothemeasurementsofSIS100andSIS300magnets,andtotheiroptimization. Furtherinformationontheworkshopcanbeaccessedfromitshomewebsite, http://indico.cern.ch/conferenceDisplay.py?confId=28832. vii Conferenceorganizingcommittee: L.Bottura,G.DeRijk,J.Kerby,L.Rossi,E.Todesco Theseproceedingshavebeenpublishedinpaperandelectronicform. Thepapercopyisinblackandwhite; theelectronicversioncontainscolourpictures. Electroniccopiescanberetrievedthrough: http://care-hhh.web.cern.ch/CARE-HHH/LUMI-06/Proceedings/proceedings_lumi06.htm Thecompilationoftheseproceedingswouldnothavebeenpossiblewithoutthehelpoftheconvenersand speakers. TheorganizationalsupportbytheworkshopsecretaryClaudineBosteelsisalsogratefullyacknowl- edged. In particular, we would like to thank all the participants for their stimulating contributions and lively discussions. TheWAMSDOworkshopwassponsoredandsupportedbytheEuropeanCommunity-ResearchInfrastruc- ture Activity under the FP6 “Structuring the European Research Area” programme (CARE, contract number RII3-CT-2003-506395). Geneva,15December2008 E.Todesco viii Contents Preface ........................................................................................... v RequirementsformagnetR&D (convener: P.Lebrun) UpgradescenariofortheLHCcomplex1 L.Evans LHCinteractionregionupgrade-phaseI R.Ostojic ................................................1 MagnetsforLinacs1 M.Tartaglia Magnetsforneutrinoandmuonphysics1 A.Blondel MagnetR&DformuoncollidersatFermilab1 M.Lamm Low-temperaturesuperconductors (conveners: R.Flu¨kiger,L.Bottura,T.Nakamoto) Advancesinlow-lossNb-Tistrandandcable M.Wilson ............................................8 Low-losswiredesignfortheDiSCoRaPdipole G.Volpini .........................................13 MagnetizationmeasurementsandanalysesonthinfilamentNb-TiwiresforSIS300synchrotron superconductingdipoles U.Gambardella ........................................................16 AdvancesinITER-relevantNb-TiandNb Snstrandsandlow-lossNb-TistrandsinRF V.Pantsyrny ...19 3 AdvancesinNb Snperformance A.Godeke ......................................................24 3 OptimizationoftheheattreatmentforNEDPITNb Snstrand T.Boutboul ..........................28 3 MetallographicinvestigationoffracturebehaviorinITER-styleNb Snsuperconductingstrands 3 M.Jewell .......................................................................................30 DevelopmentofhighcurrentNb SnRutherfordcables1 A.Godeke 3 SynchrotronradiationtechniquesforthecharacterizationofNb Snsuperconductors C.Scheuerlein ....33 3 ElectromechanicalbehaviourofPITNb SnwiresforNED B.Seeber ...............................37 3 InterstrandcouplingandmagnetizationinNb SnRutherfordcables T.Collings ......................42 3 StabilityinNb Sn1 M.Sumption 3 Self-fieldinstabilitiesinhigh-J Nb Snstrands: theeffectofcopperRRR B.Bordini .................51 c 3 Axialandtransversestress-straincharacterizationofRRPNb Snstrand2 A.Nijhuis 3 IrradiationeffectsinlowT superconductors R.Flu¨kiger ..........................................55 c ResultsofconductortestinginSULTAN:areview R.Wesche ......................................68 CablestabilityforGSIlikemagnets1 G.Willering 1Apaperwasnotsubmittedtotheproceedings.However,theslidespresentedareavailableinelectronicformathttp://indico. cern.ch/conferenceDisplay.py?confId=28832. 2PaperpublishedasA.Nijhuis,Y.Ilyin,W.Abbas,‘Axialandtransversestress-straincharacterisationoftheEUdipolehighcurrent densityNb3Snstrand’,Supercond.Sci.Technol.21(2008)065001. ix High-temperaturesuperconductors (conveners: A.BallarinoandA.Siemko) CurrentMgB wireperformanceandtheirindustrialdevelopment G.Grasso ........................78 2 ThereactiveMg-liquidinfiltrationtoobtainlongsuperconductingMgB cables G.Giunchi ...........83 2 AdvancesinHTSmaterials P.Tixador ...........................................................89 HTSapplications M.Noe .......................................................................94 Wind-and-reactBi-2212acceleratormagnettechnology1 G.Sabbi Industrysession (convener: H.TenKate) LuvataCompanyPresentation1 A.Baldini EAScompanypresentation1 M.Thoener StatusandperspectivesatBabcockNoell W.Walter ...............................................98 ManufacturingofthefirstSIS100fullsize-model1 G.Sikler ASGcompany1 R.Penco High-fieldmagnets (conveners: E.TodescoandG.L.Sabbi) MagnetsforthephaseILHCupgrade P.Fessia ................................................. 101 Nb SnacceleratormagnetandsuperconductorR&DatFermilab1 A.Zlobin 3 TestresultsofHD2,ahighfieldNb Sndipolewitha36mmbore P.Ferracin ......................105 3 Nb SnmagnetdevelopmentforLHCluminosityupgrade P.Wanderer .............................108 3 Shell-basedsupportstructuresforNb Snacceleratorquadrupolemagnets P.Ferracin ...............114 3 TestsresultsofNb Snquadrupolemagnetsusingashell-basedsupportstructure S.Caspi ........... 117 3 Nb SnquadrupoledesignsfortheLHCupgrades H.Felice .......................................120 3 15Tandbeyond-Dipolesandquadrupoles G.Sabbi ............................................123 ThehighfieldmagnetprograminEurope G.DeRijk ............................................ 128 Nb SnquadrupoledevelopmentatCEA/Saclay J.M.Rifflet ......................................131 3 Nb AlhighfieldacceleratormagnetR&D K.Sasaki .............................................132 3 Othermagnetprojects (convener: J.Kerby) Fusionvsaccelerator(ITERandDAprograms)1 A.Vostner TheBi-2212conductorandmagnetprogramattheNationalHighMagneticFieldLaboratory D.Larbalestier ................................................................................136 StatusofthesuperconductingmagnetsystemfortheJ-PARCneutrinobeamline T.Nakamoto .......139 1Apaperwasnotsubmittedtotheproceedings.However,theslidespresentedareavailableinelectronicformathttp://indico. cern.ch/conferenceDisplay.py?confId=28832. x