000070271 001__ 70271
000070271 005__ 20160902142302.0
000070271 0247_ $$2DOI$$a10.5170/CERN-2016-004
000070271 035__ $$9INSPIRETeX$$aCLIC:2016zwp
000070271 035__ $$9CDS$$a2210892
000070271 035__ $$9arXiv$$aoai:arXiv.org:1608.07537
000070271 037__ $$aCERN-2016-004
000070271 037__ $$9arXiv$$aarXiv:1608.07537$$cphysics.acc-ph
000070271 100__ $$aBoland, M J$$uU. Melbourne (main)
000070271 245__ $$9arXiv$$aUpdated baseline for a staged Compact Linear Collider
000070271 246__ $$9arXiv$$aUpdated baseline for a staged Compact Linear Collider
000070271 269__ $$c2016-08-12
000070271 300__ $$a57
000070271 500__ $$9arXiv$$a57 pages, 27 figures, 12 tables, published as CERN Yellow Report
000070271 520__ $$9arXiv$$aThe Compact Linear Collider (CLIC) is a multi-TeV high-luminosity linear e+e- collider under development. For an optimal exploitation of its physics potential, CLIC is foreseen to be built and operated in a staged approach with three centre-of-mass energy stages ranging from a few hundred GeV up to 3 TeV. The first stage will focus on precision Standard Model physics, in particular Higgs and top-quark measurements. Subsequent stages will focus on measurements of rare Higgs processes, as well as searches for new physics processes and precision measurements of new states, e.g. states previously discovered at LHC or at CLIC itself. In the 2012 CLIC Conceptual Design Report, a fully optimised 3 TeV collider was presented, while the proposed lower energy stages were not studied to the same level of detail. This report presents an updated baseline staging scenario for CLIC. The scenario is the result of a comprehensive study addressing the performance, cost and power of the CLIC accelerator complex as a function of centre-of-mass energy and it targets optimal physics output based on the current physics landscape. The optimised staging scenario foresees three main centre-of-mass energy stages at 380 GeV, 1.5 TeV and 3 TeV for a full CLIC programme spanning 22 years. For the first stage, an alternative to the CLIC drive beam scheme is presented in which the main linac power is produced using X-band klystrons.
000070271 540__ $$barXiv$$uhttp://creativecommons.org/licenses/by/4.0/
000070271 65017 $$2arXiv$$aphysics.acc-ph
000070271 65017 $$2INSPIRE$$aAccelerators
000070271 65017 $$2arXiv$$ahep-ex
000070271 65017 $$2INSPIRE$$aExperiment-HEP
000070271 693__ $$aCLIC$$eCLICdp
000070271 695__ $$2INSPIRE$$a* Automatic Keywords *
000070271 695__ $$2INSPIRE$$9bibclassify$$anew physics: search for
000070271 695__ $$2INSPIRE$$9bibclassify$$aCERN CLIC
000070271 695__ $$2INSPIRE$$9bibclassify$$alinear collider
000070271 695__ $$2INSPIRE$$9bibclassify$$alinear accelerator
000070271 695__ $$2INSPIRE$$9bibclassify$$aCERN LHC Coll
000070271 695__ $$2INSPIRE$$9bibclassify$$aaccelerator
000070271 695__ $$2INSPIRE$$9bibclassify$$aperformance
000070271 695__ $$2INSPIRE$$9bibclassify$$alandscape
000070271 695__ $$2INSPIRE$$9bibclassify$$aelectron
000070271 695__ $$2INSPIRE$$9bibclassify$$acavity
000070271 695__ $$2INSPIRE$$9bibclassify$$acosts
000070271 700__ $$aFelzmann, U$$uU. Melbourne (main)
000070271 700__ $$aGiansiracusa, P J$$uU. Melbourne (main)
000070271 700__ $$aLucas, T G$$uU. Melbourne (main)
000070271 700__ $$aRassool, R P$$uU. Melbourne (main)
000070271 700__ $$aBalazs, C$$uMonash U.
000070271 700__ $$aCharles, T K$$uMonash U.
000070271 700__ $$aAfanaciev, K$$uBelarus State U.
000070271 700__ $$aEmeliantchik, I$$uBelarus State U.
000070271 700__ $$aIgnatenko, A$$uBelarus State U.
000070271 700__ $$aMakarenko, V$$uBelarus State U.
000070271 700__ $$aShumeiko, N$$uBelarus State U.
000070271 700__ $$aPatapenka, A$$uJoint Inst. Power Nucl. Res., Minsk
000070271 700__ $$aZhuk, I$$uJoint Inst. Power Nucl. Res., Minsk
000070271 700__ $$aAbusleme Hoffman, A C$$uChile U., Catolica
000070271 700__ $$aDiaz Gutierrez, M A$$uChile U., Catolica
000070271 700__ $$aGonzalez, M Vogel$$uChile U., Catolica
000070271 700__ $$aChi, Y$$uBeijing, Inst. High Energy Phys.
000070271 700__ $$aHe, X$$uBeijing, Inst. High Energy Phys.
000070271 700__ $$aPei, G$$uBeijing, Inst. High Energy Phys.
000070271 700__ $$aPei, S$$uBeijing, Inst. High Energy Phys.
000070271 700__ $$aShu, G$$uBeijing, Inst. High Energy Phys.
000070271 700__ $$aWang, X$$uBeijing, Inst. High Energy Phys.
000070271 700__ $$aZhang, J$$uBeijing, Inst. High Energy Phys.
000070271 700__ $$aZhao, F$$uBeijing, Inst. High Energy Phys.
000070271 700__ $$aZhou, Z$$uBeijing, Inst. High Energy Phys.
000070271 700__ $$aChen, H$$uTsinghua U., Beijing
000070271 700__ $$aGao, Y$$uTsinghua U., Beijing
000070271 700__ $$aHuang, W$$uTsinghua U., Beijing
000070271 700__ $$aKuang, Y P$$uTsinghua U., Beijing
000070271 700__ $$aLi, B$$uTsinghua U., Beijing
000070271 700__ $$aLi, Y$$uTsinghua U., Beijing
000070271 700__ $$aShao, J$$uTsinghua U., Beijing
000070271 700__ $$aShi, J$$uTsinghua U., Beijing
000070271 700__ $$aTang, C$$uTsinghua U., Beijing
000070271 700__ $$aWu, X$$uTsinghua U., Beijing
000070271 700__ $$aMa, L$$uShandong U.
000070271 700__ $$aHan, Y$$uShandong U.
000070271 700__ $$aFang, W$$uSINAP, Shanghai
000070271 700__ $$aGu, Q$$uSINAP, Shanghai
000070271 700__ $$aHuang, D$$uSINAP, Shanghai
000070271 700__ $$aHuang, X$$uSINAP, Shanghai
000070271 700__ $$aTan, J$$uSINAP, Shanghai
000070271 700__ $$aWang, Z$$uSINAP, Shanghai
000070271 700__ $$aZhao, Z$$uSINAP, Shanghai
000070271 700__ $$aLaštovička, T$$uPrague, Inst. Phys.
000070271 700__ $$aUggerhoj, U$$uAarhus U. (main)
000070271 700__ $$aWistisen, T N$$uAarhus U. (main)
000070271 700__ $$aAabloo, A$$uTartu U.
000070271 700__ $$aEimre, K$$uTartu U.
000070271 700__ $$aKuppart, K$$uTartu U.
000070271 700__ $$aVigonski, S$$uTartu U.
000070271 700__ $$aZadin, V$$uTartu U.
000070271 700__ $$aAicheler, M$$uHelsinki Inst. of Phys.
000070271 700__ $$aBaibuz, E$$uHelsinki Inst. of Phys.
000070271 700__ $$aBrücken, E$$uHelsinki Inst. of Phys.
000070271 700__ $$aDjurabekova, F$$uHelsinki Inst. of Phys.$$uHelsinki U.
000070271 700__ $$aEerola, P$$uHelsinki Inst. of Phys.$$uHelsinki U.
000070271 700__ $$aGarcia, F$$uHelsinki Inst. of Phys.
000070271 700__ $$aHaeggström, E$$uHelsinki Inst. of Phys.$$uHelsinki U.
000070271 700__ $$aHuitu, K$$uHelsinki Inst. of Phys.$$uHelsinki U.
000070271 700__ $$aJansson, V$$uHelsinki Inst. of Phys.$$uHelsinki U.
000070271 700__ $$aKarimaki, V$$uHelsinki Inst. of Phys.
000070271 700__ $$aKassamakov, I$$uHelsinki Inst. of Phys.$$uHelsinki U.
000070271 700__ $$aKyritsakis, A$$uHelsinki Inst. of Phys.
000070271 700__ $$aLehti, S$$uHelsinki Inst. of Phys.
000070271 700__ $$aMeriläinen, A$$uHelsinki Inst. of Phys.$$uHelsinki U.
000070271 700__ $$aMontonen, R$$uHelsinki Inst. of Phys.$$uHelsinki U.
000070271 700__ $$aNiinikoski, T$$uHelsinki Inst. of Phys.
000070271 700__ $$aNordlund, K$$uHelsinki Inst. of Phys.$$uHelsinki U.
000070271 700__ $$aÖsterberg, K$$uHelsinki Inst. of Phys.$$uHelsinki U.
000070271 700__ $$aParekh, M$$uHelsinki Inst. of Phys.$$uHelsinki U.$$uAalto U.
000070271 700__ $$aTörnqvist, N A$$uHelsinki Inst. of Phys.
000070271 700__ $$aVäinölä, J$$uHelsinki Inst. of Phys.
000070271 700__ $$aVeske, M$$uHelsinki Inst. of Phys.
000070271 700__ $$aFarabolini, W$$uSaclay
000070271 700__ $$aMollard, A$$uSaclay
000070271 700__ $$aNapoly, O$$uSaclay
000070271 700__ $$aPeauger, F$$uSaclay
000070271 700__ $$aPlouin, J$$uSaclay
000070271 700__ $$aBambade, P$$uOrsay, LAL
000070271 700__ $$aChaikovska, I$$uOrsay, LAL
000070271 700__ $$aChehab, R$$uOrsay, LAL
000070271 700__ $$aDavier, M$$uOrsay, LAL
000070271 700__ $$aKaabi, W$$uOrsay, LAL
000070271 700__ $$aKou, E$$uOrsay, LAL
000070271 700__ $$aLeDiberder, F$$uOrsay, LAL
000070271 700__ $$aPöschl, R$$uOrsay, LAL
000070271 700__ $$aZerwas, D$$uOrsay, LAL
000070271 700__ $$aAimard, B$$uAnnecy, LAPP
000070271 700__ $$aBalik, G$$uAnnecy, LAPP
000070271 700__ $$aBaud, J-P$$uAnnecy, LAPP
000070271 700__ $$aBlaising, J-J$$uAnnecy, LAPP
000070271 700__ $$aBrunetti, L$$uAnnecy, LAPP
000070271 700__ $$aChefdeville, M$$uAnnecy, LAPP
000070271 700__ $$aDrancourt, C$$uAnnecy, LAPP
000070271 700__ $$aGeoffroy, N$$uAnnecy, LAPP
000070271 700__ $$aJacquemier, J$$uAnnecy, LAPP
000070271 700__ $$aJeremie, A$$uAnnecy, LAPP
000070271 700__ $$aKaryotakis, Y$$uAnnecy, LAPP
000070271 700__ $$aNappa, J M$$uAnnecy, LAPP
000070271 700__ $$aVilalte, S$$uAnnecy, LAPP
000070271 700__ $$aVouters, G$$uAnnecy, LAPP
000070271 700__ $$aBernard, A$$uKIT, Karlsruhe
000070271 700__ $$aPeric, I$$uKIT, Karlsruhe
000070271 700__ $$aGabriel, M$$uMunich, Max Planck Inst.
000070271 700__ $$aSimon, F$$uMunich, Max Planck Inst.
000070271 700__ $$aSzalay, M$$uMunich, Max Planck Inst.
000070271 700__ $$avan der Kolk, N$$uMunich, Max Planck Inst.
000070271 700__ $$aAlexopoulos, T$$uNatl. Tech. U., Athens
000070271 700__ $$aGazis, E N$$uNatl. Tech. U., Athens
000070271 700__ $$aGazis, N$$uNatl. Tech. U., Athens
000070271 700__ $$aIkarios, E$$uNatl. Tech. U., Athens
000070271 700__ $$aKostopoulos, V$$uNatl. Tech. U., Athens$$uPatras U.
000070271 700__ $$aKourkoulis, S$$uNatl. Tech. U., Athens
000070271 700__ $$aGupta, P D$$uRaja Ramanna Ctr.
000070271 700__ $$aShrivastava, P$$uRaja Ramanna Ctr.
000070271 700__ $$aArfaei, H$$uIPM, Tehran
000070271 700__ $$aDayyani, M K$$uIPM, Tehran
000070271 700__ $$aGhasem, H$$uIPM, Tehran$$uCERN
000070271 700__ $$aHajari, S S$$uIPM, Tehran
000070271 700__ $$aShaker, H$$uIPM, Tehran$$uCERN
000070271 700__ $$aAshkenazy, Y$$uHebrew U.
000070271 700__ $$aAbramowicz, H$$uTel Aviv U. (main)
000070271 700__ $$aBenhammou, Y$$uTel Aviv U. (main)
000070271 700__ $$aBorysov, O$$uTel Aviv U. (main)
000070271 700__ $$aKananov, S$$uTel Aviv U. (main)
000070271 700__ $$aLevy, A$$uTel Aviv U. (main)
000070271 700__ $$aLevy, I$$uTel Aviv U. (main)
000070271 700__ $$aRosenblat, O$$uTel Aviv U. (main)
000070271 700__ $$aD'Auria, G$$uSincrotrone Trieste
000070271 700__ $$aDi Mitri, S$$uSincrotrone Trieste
000070271 700__ $$aAbe, T$$uKEK, Tsukuba
000070271 700__ $$aAryshev, A$$uKEK, Tsukuba
000070271 700__ $$aHigo, T$$uKEK, Tsukuba
000070271 700__ $$aMakida, Y$$uKEK, Tsukuba
000070271 700__ $$aMatsumoto, S$$uKEK, Tsukuba
000070271 700__ $$aShidara, T$$uKEK, Tsukuba
000070271 700__ $$aTakatomi, T$$uKEK, Tsukuba
000070271 700__ $$aTakubo, Y$$uKEK, Tsukuba
000070271 700__ $$aTauchi, T$$uKEK, Tsukuba
000070271 700__ $$aToge, N$$uKEK, Tsukuba
000070271 700__ $$aUeno, K$$uKEK, Tsukuba
000070271 700__ $$aUrakawa, J$$uKEK, Tsukuba
000070271 700__ $$aYamamoto, A$$uKEK, Tsukuba$$uCERN
000070271 700__ $$aYamanaka, M$$uKEK, Tsukuba
000070271 700__ $$aRaboanary, R$$uAntananarivo U.
000070271 700__ $$aHart, R$$uNIKHEF, Amsterdam
000070271 700__ $$avan der Graaf, H$$uNIKHEF, Amsterdam
000070271 700__ $$aEigen, G$$uBergen U.
000070271 700__ $$aZalieckas, J$$uBergen U.
000070271 700__ $$aAdli, E$$uOslo U.$$uCERN
000070271 700__ $$aLillestøl, R$$uOslo U.
000070271 700__ $$aMalina, L$$uOslo U.$$uCERN
000070271 700__ $$aPfingstner, J$$uOslo U.
000070271 700__ $$aSjobak, K N$$uOslo U.$$uCERN
000070271 700__ $$aAhmed, W$$uNCP, Islamabad
000070271 700__ $$aAsghar, M I$$uNCP, Islamabad
000070271 700__ $$aHoorani, H$$uNCP, Islamabad
000070271 700__ $$aBugiel, S$$uAGH-UST, Cracow
000070271 700__ $$aDasgupta, R$$uAGH-UST, Cracow
000070271 700__ $$aFirlej, M$$uAGH-UST, Cracow
000070271 700__ $$aFiutowski, T A$$uAGH-UST, Cracow
000070271 700__ $$aIdzik, M$$uAGH-UST, Cracow
000070271 700__ $$aKopec, M$$uAGH-UST, Cracow
000070271 700__ $$aKuczynska, M$$uAGH-UST, Cracow
000070271 700__ $$aMoron, J$$uAGH-UST, Cracow
000070271 700__ $$aSwientek, K P$$uAGH-UST, Cracow
000070271 700__ $$aDaniluk, W$$uCracow, INP
000070271 700__ $$aKrupa, B$$uCracow, INP
000070271 700__ $$aKucharczyk, M$$uCracow, INP
000070271 700__ $$aLesiak, T$$uCracow, INP
000070271 700__ $$aMoszczynski, A$$uCracow, INP
000070271 700__ $$aPawlik, B$$uCracow, INP
000070271 700__ $$aSopicki, P$$uCracow, INP
000070271 700__ $$aWojtoń, T$$uCracow, INP
000070271 700__ $$aZawiejski, L$$uCracow, INP
000070271 700__ $$aKalinowski, J$$uWarsaw U.
000070271 700__ $$aKrawczyk, M$$uWarsaw U.
000070271 700__ $$aŻarnecki, A F$$uWarsaw U.
000070271 700__ $$aFiru, E$$uBucharest, Inst. Space Science
000070271 700__ $$aGhenescu, V$$uBucharest, Inst. Space Science
000070271 700__ $$aNeagu, A T$$uBucharest, Inst. Space Science
000070271 700__ $$aPreda, T$$uBucharest, Inst. Space Science
000070271 700__ $$aZgura, I-S$$uBucharest, Inst. Space Science
000070271 700__ $$aAloev, A$$uDubna, JINR
000070271 700__ $$aAzaryan, N$$uDubna, JINR
000070271 700__ $$aBudagov, J$$uDubna, JINR
000070271 700__ $$aChizhov, M$$uDubna, JINR
000070271 700__ $$aFilippova, M$$uDubna, JINR
000070271 700__ $$aGlagolev, V$$uDubna, JINR
000070271 700__ $$aGongadze, A$$uDubna, JINR
000070271 700__ $$aGrigoryan, S$$uDubna, JINR
000070271 700__ $$aGudkov, D$$uDubna, JINR
000070271 700__ $$aKarjavine, V$$uDubna, JINR
000070271 700__ $$aLyablin, M$$uDubna, JINR
000070271 700__ $$aOlyunin, A$$uDubna, JINR$$uCERN
000070271 700__ $$aSamochkine, A$$uDubna, JINR
000070271 700__ $$aSapronov, A$$uDubna, JINR
000070271 700__ $$aShirkov, G$$uDubna, JINR
000070271 700__ $$aSoldatov, V$$uDubna, JINR
000070271 700__ $$aSolodko, A$$uDubna, JINR$$uCERN
000070271 700__ $$aSolodko, E$$uDubna, JINR$$uCERN
000070271 700__ $$aTrubnikov, G$$uDubna, JINR
000070271 700__ $$aTyapkin, I$$uDubna, JINR
000070271 700__ $$aUzhinsky, V$$uDubna, JINR
000070271 700__ $$aVorozhtov, A$$uDubna, JINR
000070271 700__ $$aLevichev, E$$uNovosibirsk, IYF
000070271 700__ $$aMezentsev, N$$uNovosibirsk, IYF
000070271 700__ $$aPiminov, P$$uNovosibirsk, IYF
000070271 700__ $$aShatilov, D$$uNovosibirsk, IYF
000070271 700__ $$aVobly, P$$uNovosibirsk, IYF
000070271 700__ $$aZolotarev, K$$uNovosibirsk, IYF
000070271 700__ $$aBozovic-Jelisavcic, I$$uVINCA Inst. Nucl. Sci., Belgrade
000070271 700__ $$aKacarevic, G$$uVINCA Inst. Nucl. Sci., Belgrade
000070271 700__ $$aLukic, S$$uVINCA Inst. Nucl. Sci., Belgrade
000070271 700__ $$aMilutinovic-Dumbelovic, G$$uVINCA Inst. Nucl. Sci., Belgrade
000070271 700__ $$aPandurovic, M$$uVINCA Inst. Nucl. Sci., Belgrade
000070271 700__ $$aIriso, U$$uCELLS - ALBA, LLS
000070271 700__ $$aPerez, F$$uCELLS - ALBA, LLS
000070271 700__ $$aPont, M$$uCELLS - ALBA, LLS
000070271 700__ $$aTrenado, J$$uU. Barcelona (main)
000070271 700__ $$aAguilar-Benitez, M$$uMadrid, CIEMAT
000070271 700__ $$aCalero, J$$uMadrid, CIEMAT
000070271 700__ $$aGarcia-Tabares, L$$uMadrid, CIEMAT
000070271 700__ $$aGavela, D$$uMadrid, CIEMAT
000070271 700__ $$aGutierrez, J L$$uMadrid, CIEMAT
000070271 700__ $$aLopez, D$$uMadrid, CIEMAT
000070271 700__ $$aToral, F$$uMadrid, CIEMAT
000070271 700__ $$aMoya, D$$uCantabria Inst. of Phys.
000070271 700__ $$aRuiz-Jimeno, A$$uCantabria Inst. of Phys.
000070271 700__ $$aVila, I$$uCantabria Inst. of Phys.
000070271 700__ $$aArgyropoulos, T$$uValencia U., IFIC$$uCERN
000070271 700__ $$aBlanch Gutierrez, C$$uValencia U., IFIC
000070271 700__ $$aBoronat, M$$uValencia U., IFIC
000070271 700__ $$aEsperante, D$$uValencia U., IFIC$$uCERN
000070271 700__ $$aFaus-Golfe, A$$uValencia U., IFIC
000070271 700__ $$aFuster, J$$uValencia U., IFIC
000070271 700__ $$aFuster Martinez, N$$uValencia U., IFIC
000070271 700__ $$aGalindo Muñoz, N$$uValencia U., IFIC
000070271 700__ $$aGarcía, I$$uValencia U., IFIC
000070271 700__ $$aGiner Navarro, J$$uValencia U., IFIC$$uCERN
000070271 700__ $$aRos, E$$uValencia U., IFIC
000070271 700__ $$aVos, M$$uValencia U., IFIC
000070271 700__ $$aBrenner, R$$uUppsala U. (main)
000070271 700__ $$aEkelöf, T$$uUppsala U. (main)
000070271 700__ $$aJacewicz, M$$uUppsala U. (main)
000070271 700__ $$aÖgren, J$$uUppsala U. (main)
000070271 700__ $$aOlvegård, M$$uUppsala U. (main)
000070271 700__ $$aRuber, R$$uUppsala U. (main)
000070271 700__ $$aZiemann, V$$uUppsala U. (main)
000070271 700__ $$aAguglia, D$$uCERN
000070271 700__ $$aAlipour Tehrani, N$$uCERN$$uETH, Zurich (main)
000070271 700__ $$aAloev, A$$uCERN
000070271 700__ $$aAndersson, A$$uCERN
000070271 700__ $$aAndrianala, F$$uCERN$$uAntananarivo U.
000070271 700__ $$aAntoniou, F$$uCERN
000070271 700__ $$aArtoos, K$$uCERN
000070271 700__ $$aAtieh, S$$uCERN
000070271 700__ $$aBallabriga Sune, R$$uCERN
000070271 700__ $$aBarnes, M J$$uCERN
000070271 700__ $$aBarranco Garcia, J$$uCERN
000070271 700__ $$aBartosik, H$$uCERN
000070271 700__ $$aBelver-Aguilar, C$$uCERN
000070271 700__ $$aBenot Morell, A$$uCERN$$uValencia U., IFIC
000070271 700__ $$aBett, D R$$uCERN
000070271 700__ $$aBettoni, S$$uCERN
000070271 700__ $$aBlanchot, G$$uCERN
000070271 700__ $$aBlanco Garcia, O$$uCERN
000070271 700__ $$aBonnin, X A$$uCERN
000070271 700__ $$aBrunner, O$$uCERN
000070271 700__ $$aBurkhardt, H$$uCERN
000070271 700__ $$aCalatroni, S$$uCERN
000070271 700__ $$aCampbell, M$$uCERN
000070271 700__ $$aCatalan Lasheras, N$$uCERN
000070271 700__ $$aCerqueira Bastos, M$$uCERN
000070271 700__ $$aCherif, A$$uCERN
000070271 700__ $$aChevallay, E$$uCERN
000070271 700__ $$aConstance, B$$uCERN
000070271 700__ $$aCorsini, R$$uCERN
000070271 700__ $$aCure, B$$uCERN
000070271 700__ $$aCurt, S$$uCERN
000070271 700__ $$aDalena, B$$uCERN
000070271 700__ $$aDannheim, D$$uCERN
000070271 700__ $$aDe Michele, G$$uCERN
000070271 700__ $$aDe Oliveira, L$$uCERN
000070271 700__ $$aDeelen, N$$uCERN
000070271 700__ $$aDelahaye, J P$$uCERN
000070271 700__ $$aDobers, T$$uCERN
000070271 700__ $$aDoebert, S$$uCERN
000070271 700__ $$aDraper, M$$uCERN
000070271 700__ $$aDuarte Ramos, F$$uCERN
000070271 700__ $$aDubrovskiy, A$$uCERN
000070271 700__ $$aElsener, K$$uCERN
000070271 700__ $$aEsberg, J$$uCERN
000070271 700__ $$aEsposito, M$$uCERN
000070271 700__ $$aFedosseev, V$$uCERN
000070271 700__ $$aFerracin, P$$uCERN
000070271 700__ $$aFiergolski, A$$uCERN
000070271 700__ $$aForaz, K$$uCERN
000070271 700__ $$aFowler, A$$uCERN
000070271 700__ $$aFriebel, F$$uCERN
000070271 700__ $$aFuchs, J-F$$uCERN
000070271 700__ $$aFuentes Rojas, C A$$uCERN
000070271 700__ $$aGaddi, A$$uCERN
000070271 700__ $$aGarcia Fajardo, L$$uCERN
000070271 700__ $$aGarcia Morales, H$$uCERN
000070271 700__ $$aGarion, C$$uCERN
000070271 700__ $$aGatignon, L$$uCERN
000070271 700__ $$aGayde, J-C$$uCERN
000070271 700__ $$aGerwig, H$$uCERN
000070271 700__ $$aGoldblatt, A N$$uCERN
000070271 700__ $$aGrefe, C$$uCERN
000070271 700__ $$aGrudiev, A$$uCERN
000070271 700__ $$aGuillot-Vignot, F G$$uCERN
000070271 700__ $$aGutt-Mostowy, M L$$uCERN
000070271 700__ $$aHauschild, M$$uCERN
000070271 700__ $$aHessler, C$$uCERN
000070271 700__ $$aHolma, J K$$uCERN
000070271 700__ $$aHolzer, E$$uCERN
000070271 700__ $$aHourican, M$$uCERN
000070271 700__ $$aHynds, D$$uCERN
000070271 700__ $$aInntjore Levinsen, Y$$uCERN
000070271 700__ $$aJeanneret, B$$uCERN
000070271 700__ $$aJensen, E$$uCERN
000070271 700__ $$aJonker, M$$uCERN
000070271 700__ $$aKastriotou, M$$uCERN
000070271 700__ $$aKemppinen, J M K$$uCERN
000070271 700__ $$aKieffer, R B$$uCERN
000070271 700__ $$aKlempt, W$$uCERN
000070271 700__ $$aKononenko, O$$uCERN
000070271 700__ $$aKorsback, A$$uCERN
000070271 700__ $$aKoukovini Platia, E$$uCERN
000070271 700__ $$aKovermann, J W$$uCERN
000070271 700__ $$aKozsar, C-I$$uCERN
000070271 700__ $$aKremastiotis, I$$uCERN$$uKIT, Karlsruhe
000070271 700__ $$aKulis, S$$uCERN
000070271 700__ $$aLatina, A$$uCERN
000070271 700__ $$aLeaux, F$$uCERN
000070271 700__ $$aLebrun, P$$eed.$$uCERN
000070271 700__ $$aLefevre, T$$uCERN
000070271 700__ $$aLinssen, L$$eed.$$uCERN
000070271 700__ $$aLlopart Cudie, X$$uCERN
000070271 700__ $$aMaier, A A$$uCERN
000070271 700__ $$aMainaud Durand, H$$uCERN
000070271 700__ $$aManosperti, E$$uCERN
000070271 700__ $$aMarelli, C$$uCERN
000070271 700__ $$aMarin Lacoma, E$$uCERN
000070271 700__ $$aMartin, R$$uCERN
000070271 700__ $$aMazzoni, S$$uCERN
000070271 700__ $$aMcmonagle, G$$uCERN
000070271 700__ $$aMete, O$$uCERN
000070271 700__ $$aMether, L M$$uCERN
000070271 700__ $$aModena, M$$uCERN
000070271 700__ $$aMünker, R M$$uCERN$$uU. Bonn (main)
000070271 700__ $$aMuranaka, T$$uCERN
000070271 700__ $$aNebot Del Busto, E$$uCERN
000070271 700__ $$aNikiforou, N$$uCERN
000070271 700__ $$aNisbet, D$$uCERN
000070271 700__ $$aNonglaton, J-M$$uCERN
000070271 700__ $$aNuiry, F X$$uCERN
000070271 700__ $$aNürnberg, A$$uCERN
000070271 700__ $$aOlvegard, M$$uCERN
000070271 700__ $$aOsborne, J$$uCERN
000070271 700__ $$aPapadopoulou, S$$uCERN
000070271 700__ $$aPapaphilippou, Y$$uCERN
000070271 700__ $$aPassarelli, A$$uCERN
000070271 700__ $$aPatecki, M$$uCERN
000070271 700__ $$aPazdera, L$$uCERN
000070271 700__ $$aPellegrini, D$$uCERN
000070271 700__ $$aPepitone, K$$uCERN
000070271 700__ $$aPerez, F$$uCERN
000070271 700__ $$aPerez Codina, E$$uCERN
000070271 700__ $$aPerez Fontenla, A$$uCERN
000070271 700__ $$aPersson, T H B$$uCERN
000070271 700__ $$aPetrič, M$$uCERN
000070271 700__ $$aPitters, F$$uCERN$$uTU Vienna
000070271 700__ $$aPittet, S$$uCERN
000070271 700__ $$aPlassard, F$$uCERN
000070271 700__ $$aRajamak, R$$uCERN
000070271 700__ $$aRedford, S$$uCERN
000070271 700__ $$aRenier, Y$$uCERN
000070271 700__ $$aRey, S F$$uCERN
000070271 700__ $$aRiddone, G$$uCERN
000070271 700__ $$aRinolfi, L$$uCERN
000070271 700__ $$aRodriguez Castro, E$$uCERN
000070271 700__ $$aRoloff, P$$uCERN
000070271 700__ $$aRossi, C$$uCERN
000070271 700__ $$aRude, V$$uCERN
000070271 700__ $$aRumolo, G$$uCERN
000070271 700__ $$aSailer, A$$uCERN
000070271 700__ $$aSantin, E$$uCERN
000070271 700__ $$aSchlatter, D$$uCERN
000070271 700__ $$aSchmickler, H$$uCERN
000070271 700__ $$aSchulte, D$$eed.$$uCERN
000070271 700__ $$aShipman, N$$uCERN
000070271 700__ $$aSicking, E$$eed.$$uCERN
000070271 700__ $$aSimoniello, R$$uCERN
000070271 700__ $$aSkowronski, P K$$uCERN
000070271 700__ $$aSobrino Mompean, P$$uCERN
000070271 700__ $$aSoby, L$$uCERN
000070271 700__ $$aSosin, M P$$uCERN
000070271 700__ $$aSroka, S$$uCERN
000070271 700__ $$aStapnes, S$$eed.$$uCERN
000070271 700__ $$aSterbini, G$$uCERN
000070271 700__ $$aStröm, R$$uCERN
000070271 700__ $$aSyratchev, I$$uCERN
000070271 700__ $$aTecker, F$$uCERN
000070271 700__ $$aThonet, P A$$uCERN
000070271 700__ $$aTimeo, L$$uCERN
000070271 700__ $$aTimko, H$$uCERN
000070271 700__ $$aTomas Garcia, R$$uCERN
000070271 700__ $$aValerio, P$$uCERN
000070271 700__ $$aVamvakas, A L$$uCERN
000070271 700__ $$aVivoli, A$$uCERN
000070271 700__ $$aWeber, M A$$uCERN
000070271 700__ $$aWegner, R$$uCERN
000070271 700__ $$aWendt, M$$uCERN
000070271 700__ $$aWoolley, B$$uCERN
000070271 700__ $$aWuensch, W$$uCERN
000070271 700__ $$aUythoven, J$$uCERN
000070271 700__ $$aZha, H$$uCERN
000070271 700__ $$aZisopoulos, P$$uCERN
000070271 700__ $$aBenoit, M$$uGeneva U.
000070271 700__ $$aVicente Barreto Pinto, M$$uGeneva U.
000070271 700__ $$aBopp, M$$uPSI, Villigen
000070271 700__ $$aBraun, H H$$uPSI, Villigen
000070271 700__ $$aCsatari Divall, M$$uPSI, Villigen
000070271 700__ $$aDehler, M$$uPSI, Villigen
000070271 700__ $$aGarvey, T$$uPSI, Villigen
000070271 700__ $$aRaguin, J Y$$uPSI, Villigen
000070271 700__ $$aRivkin, L$$uPSI, Villigen
000070271 700__ $$aZennaro, R$$uPSI, Villigen
000070271 700__ $$aAksoy, A$$uAnkara U., Inst. Accel. Technol.
000070271 700__ $$aNergiz, Z$$uAnkara U., Inst. Accel. Technol.
000070271 700__ $$aPilicer, E$$uAnkara U., Inst. Accel. Technol.
000070271 700__ $$aTapan, I$$uAnkara U., Inst. Accel. Technol.
000070271 700__ $$aYavas, O$$uAnkara U., Inst. Accel. Technol.
000070271 700__ $$aBaturin, V$$uSumy, Inst. Appl. Phys.
000070271 700__ $$aKholodov, R$$uSumy, Inst. Appl. Phys.
000070271 700__ $$aLebedynskyi, S$$uSumy, Inst. Appl. Phys.
000070271 700__ $$aMiroshnichenko, V$$uSumy, Inst. Appl. Phys.
000070271 700__ $$aMordyk, S$$uSumy, Inst. Appl. Phys.
000070271 700__ $$aProfatilova, I$$uSumy, Inst. Appl. Phys.
000070271 700__ $$aStorizhko, V$$uSumy, Inst. Appl. Phys.
000070271 700__ $$aWatson, N$$uBirmingham U.
000070271 700__ $$aWinter, A$$uBirmingham U.
000070271 700__ $$aGoldstein, J$$uU. Bristol (main)
000070271 700__ $$aGreen, S$$uCambridge U.
000070271 700__ $$aMarshall, J S$$uCambridge U.
000070271 700__ $$aThomson, M A$$eed.$$uCambridge U.
000070271 700__ $$aXu, B$$uCambridge U.
000070271 700__ $$aGillespie, W A$$uDundee U.
000070271 700__ $$aPan, R$$uDundee U.
000070271 700__ $$aTyrk, M A$$uDundee U.
000070271 700__ $$aProtopopescu, D$$uGlasgow U.
000070271 700__ $$aRobson, A$$uGlasgow U.
000070271 700__ $$aApsimon, R$$uLancaster U.$$uCockcroft Inst. Accel. Sci. Tech.
000070271 700__ $$aBailey, I$$uLancaster U.$$uCockcroft Inst. Accel. Sci. Tech.
000070271 700__ $$aBurt, G$$uLancaster U.$$uCockcroft Inst. Accel. Sci. Tech.
000070271 700__ $$aConstable, D$$uLancaster U.$$uCockcroft Inst. Accel. Sci. Tech.
000070271 700__ $$aDexter, A$$uLancaster U.$$uCockcroft Inst. Accel. Sci. Tech.
000070271 700__ $$aKarimian, S$$uLancaster U.$$uCockcroft Inst. Accel. Sci. Tech.
000070271 700__ $$aLingwood, C$$uLancaster U.$$uCockcroft Inst. Accel. Sci. Tech.
000070271 700__ $$aBuckland, M D$$uU. Liverpool (main)
000070271 700__ $$aCasse, G$$uU. Liverpool (main)
000070271 700__ $$aVossebeld, J$$uU. Liverpool (main)
000070271 700__ $$aBosco, A$$uJAI, UK
000070271 700__ $$aKarataev, P$$uJAI, UK
000070271 700__ $$aKruchinin, K$$uJAI, UK
000070271 700__ $$aLekomtsev, K$$uJAI, UK
000070271 700__ $$aNevay, L$$uJAI, UK
000070271 700__ $$aSnuverink, J$$uJAI, UK
000070271 700__ $$aYamakawa, E$$uJAI, UK
000070271 700__ $$aBoisvert, V$$uRoyal Holloway, U. of London
000070271 700__ $$aBoogert, S$$uRoyal Holloway, U. of London
000070271 700__ $$aBoorman, G$$uRoyal Holloway, U. of London
000070271 700__ $$aGibson, S$$uRoyal Holloway, U. of London
000070271 700__ $$aLyapin, A$$uRoyal Holloway, U. of London
000070271 700__ $$aShields, W$$uRoyal Holloway, U. of London
000070271 700__ $$aTeixeira-Dias, P$$uRoyal Holloway, U. of London
000070271 700__ $$aWest, S$$uRoyal Holloway, U. of London
000070271 700__ $$aJones, R$$uU. Manchester (main)
000070271 700__ $$aJoshi, N$$uU. Manchester (main)
000070271 700__ $$aBodenstein, R$$uJAI, UK
000070271 700__ $$aBurrows, P N$$eed.$$uOxford U.$$uJAI, UK
000070271 700__ $$aChristian, G B$$uJAI, UK
000070271 700__ $$aGamba, D$$uJAI, UK$$uCERN
000070271 700__ $$aPerry, C$$uJAI, UK
000070271 700__ $$aRoberts, J$$uJAI, UK$$uCERN
000070271 700__ $$aClarke, J A$$uDaresbury$$uCockcroft Inst. Accel. Sci. Tech.
000070271 700__ $$aCollomb, N A$$uDaresbury
000070271 700__ $$aJamison, S P$$uDaresbury$$uCockcroft Inst. Accel. Sci. Tech.
000070271 700__ $$aShepherd, B J A$$uDaresbury$$uCockcroft Inst. Accel. Sci. Tech.
000070271 700__ $$aWalsh, D$$uDaresbury$$uCockcroft Inst. Accel. Sci. Tech.
000070271 700__ $$aDemarteau, M$$uArgonne
000070271 700__ $$aRepond, J$$uArgonne
000070271 700__ $$aWeerts, H$$uArgonne
000070271 700__ $$aXia, L$$uArgonne
000070271 700__ $$aWells, J D$$uMichigan U.
000070271 700__ $$aAdolphsen, C$$uSLAC
000070271 700__ $$aBarklow, T$$uSLAC
000070271 700__ $$aBreidenbach, M$$uSLAC
000070271 700__ $$aGraf, N$$uSLAC
000070271 700__ $$aHewett, J$$uSLAC
000070271 700__ $$aMarkiewicz, T$$uSLAC
000070271 700__ $$aMcCormick, D$$uSLAC
000070271 700__ $$aMoffeit, K$$uSLAC
000070271 700__ $$aNosochkov, Y$$uSLAC
000070271 700__ $$aOriunno, M$$uSLAC
000070271 700__ $$aPhinney, N$$uSLAC
000070271 700__ $$aRizzo, T$$uSLAC
000070271 700__ $$aTantawi, S$$uSLAC
000070271 700__ $$aWang, F$$uSLAC
000070271 700__ $$aWang, J$$uSLAC
000070271 700__ $$aWhite, G$$uSLAC
000070271 700__ $$aWoodley, M$$uSLAC
000070271 710__ $$gCLIC
000070271 710__ $$gCLICdp
000070271 8564_ $$s109678$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Optimisation_tau_n_3000_08x.png$$y00004 The RF pulse length $\tau_{\text{RF}}$ and number of bunches $n_\text{b}$ for the most power efficient structures at 3\,TeV. The different colours indicate the relative cost increase $\Delta\,c$ with respect to the minimum cost. Comparison with the reference line shows that for equal pulse length fewer bunches are needed when better RF performance is assumed. Left: For the conservative RF limits ($S=1.0$) and a gradient of $G=100$\,MV/m. Right: For $S=1.2$ and a gradient of $G=120$\,MV/m.
000070271 8564_ $$s124002$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Optimisation_tau_n_3000_10.png$$y00003 The RF pulse length $\tau_{\text{RF}}$ and number of bunches $n_\text{b}$ for the most power efficient structures at 3\,TeV. The different colours indicate the relative cost increase $\Delta\,c$ with respect to the minimum cost. Comparison with the reference line shows that for equal pulse length fewer bunches are needed when better RF performance is assumed. Left: For the conservative RF limits ($S=1.0$) and a gradient of $G=100$\,MV/m. Right: For $S=1.2$ and a gradient of $G=120$\,MV/m.
000070271 8564_ $$s12520$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_LuminosityPerYear380_font.png$$y00012 Luminosity per year in the considered staging scenario. Years are counted from the start of beam commissioning. This figure includes luminosity ramp-up of four years (5\%, 10\%, 25\%, 50\%) in the first stage and two years (25\%, 50\%) in subsequent stages.
000070271 8564_ $$s12567$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_IntegratedLuminosity380_font.png$$y00013 Integrated luminosity in the considered staging scenario. Years are counted from the start of beam commissioning. The luminosity ramp-up corresponds to what is described in \autoref{fig:LumiPerYear}.
000070271 8564_ $$s174162$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Optimisation_scatter_new2.png$$y00005 Left: Cost and power consumption of the different possible designs at a centre-of-mass energy of 380\,GeV and a luminosity of $L=1.5\times10^{34}\,\text{cm}^{-2}\text{s}^{-1}$. Different safety margins for the gradient are used. Right: Cost and power consumption with a gradient safety margin of 10\% ($S=1.1$) for different luminosities (in units of $10^{34}\text{cm}^{-2}\text{s}^{-1}$).
000070271 8564_ $$s1974150$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Region-Only-CLIC.png$$y00009 CLIC footprints near CERN, showing the three implementation stages.
000070271 8564_ $$s217931$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Optimisation_stage_new.png$$y00007 One of the potential staging concepts. In this solution, the modules at the beginning of the previous main linac are moved to the new beginning during the upgrade.
000070271 8564_ $$s2765$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Optimisation_cost_cmp.png$$y00008 The minimum cost of the first energy stage as a function of the luminosity target. The fully optimised (opt.) case and the one adapted for the upgrade (match.) are shown.
000070271 8564_ $$s34365$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Optimisation_contour_3tev_10.png$$y00001 Possible average aperture radii $a$ normalised to the RF wavelength $\lambda$ and number of cells $N_\text{c}$ for the structures that meet the luminosity goal at 3\,TeV (in yellow). The most efficient structures, which do not require more than 1\%, 3\% or 5\% higher power consumption than the best, are indicated by blue, purple and orange colours. For all parameter combinations without a point, no structure solution is found. The spot ``$\times$'' indicates the parameters of the CDR structure (``CLIC\_G''). Left: The solutions based on the current state of the conservative RF limits. Right: The solutions for $S=1.2$.
000070271 8564_ $$s42754$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Optimisation_KlystronScheme.png$$y00019 Conceptual Design of an RF unit for a klystron-based CLIC main linac. Two klystrons produce RF pulses, which are combined into a single double-power pulse. The pulse passes the correction cavities chain, which modifies the pulse shape, and is then split into two pulses of half the power in order to feed two SLED pulse compressors. Each SLED shortens the pulse by increasing the power; two compressors are used to limit the final power in each of them. Finally, the pulses are split and distributed into five accelerating structures.
000070271 8564_ $$s432823$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_CLIC_timeline.png$$y00020 An outline of the CLIC project timeline from the current development phase up to future first beams at the 380\,\gev CLIC energy stage.
000070271 8564_ $$s4643$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_cost.png$$y00018 Value estimates of CLIC 500\,GeV A, 500\,GeV B and 380\,GeV, in MCHF of December 2010. The 500\,GeV numbers are taken from the CDR~\cite{CLICCDR_vol3}.
000070271 8564_ $$s4954$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Optimisation_DerivationMachineParameters.png$$y00000 An illustration of the accelerator parameter derivation based on the parameters of the main linac accelerating structure.
000070271 8564_ $$s5701$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Power2.png$$y00015 Estimated power consumption of CLIC in MW at a centre-of-mass energy of 380\,GeV. The contributions add up to a total of 252\,MW. Left: breakdown of power consumption between different domains of the accelerator complex. Right: breakdown of power consumption between different technical systems.
000070271 8564_ $$s61574$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Optimisation_contour_3tev_08.png$$y00002 Possible average aperture radii $a$ normalised to the RF wavelength $\lambda$ and number of cells $N_\text{c}$ for the structures that meet the luminosity goal at 3\,TeV (in yellow). The most efficient structures, which do not require more than 1\%, 3\% or 5\% higher power consumption than the best, are indicated by blue, purple and orange colours. For all parameter combinations without a point, no structure solution is found. The spot ``$\times$'' indicates the parameters of the CDR structure (``CLIC\_G''). Left: The solutions based on the current state of the conservative RF limits. Right: The solutions for $S=1.2$.
000070271 8564_ $$s6294$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_operationSchedule.png$$y00016 Operation schedule in ``normal'' year (days/year).
000070271 8564_ $$s6816$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Power1.png$$y00014 Estimated power consumption of CLIC in MW at a centre-of-mass energy of 380\,GeV. The contributions add up to a total of 252\,MW. Left: breakdown of power consumption between different domains of the accelerator complex. Right: breakdown of power consumption between different technical systems.
000070271 8564_ $$s6881$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_CLIC-layout-380GeV.png$$y00010 Overview of the CLIC layout at $\sqrt{s}=380$\,GeV. Only one drive beam complex is needed for the first (and second) stage of CLIC.
000070271 8564_ $$s7558$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_CLIC-layout-3TeV.png$$y00011 Overview of the CLIC layout at $\sqrt{s}=3$\,TeV.
000070271 8564_ $$s88057$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_Optimisation_scatter_new1.png$$y00006 Left: Cost and power consumption of the different possible designs at a centre-of-mass energy of 380\,GeV and a luminosity of $L=1.5\times10^{34}\,\text{cm}^{-2}\text{s}^{-1}$. Different safety margins for the gradient are used. Right: Cost and power consumption with a gradient safety margin of 10\% ($S=1.1$) for different luminosities (in units of $10^{34}\text{cm}^{-2}\text{s}^{-1}$).
000070271 8564_ $$s9473$$uhttp://inspirehep.net/record/1484159/files/Figures_Accelerator_EnergyConsumption.png$$y00017 Estimated yearly energy consumption of CLIC.
000070271 8564_ $$s5347125$$uhttp://inspirehep.net/record/1484159/files/arXiv:1608.07537.pdf
000070271 909CO $$ooai:inspirehep.net:1484159$$pCERN$$pINSPIRE:HEP$$pCERN:arXiv$$pCDS
000070271 980__ $$aCORE
000070271 980__ $$aarXiv
000070271 980__ $$aCiteable
000070271 980__ $$aHEP
000070271 999C6 $$a0-0-0-1-1-0-1$$t2016-08-30 04:24:26$$vInvenio/1.1.2.1260-aa76f refextract/1.5.44$$vcontent.pdf;2
000070271 999C5 $$mCompact Linear Collider (CLIC), last accessed 30.08., URL:$$o1$$uhttp://clic-study.web.cern.ch/$$y2016
000070271 999C5 $$mCLIC detector and physics (CLICdp), last accessed 30.08., URL:$$o2$$uhttp://clicdp.web.cern.ch/$$y2016
000070271 999C5 $$01228241$$adoi:10.5170/CERN-2012-007$$hM. Aicheler et al.$$mCLIC Conceptual Design Report: A Multi-TeV Linear Collider Based on CLIC Technology Geneva, Switzerland,, DOI:$$o3$$rCERN-2012-007$$y2012
000070271 999C5 $$01090842$$adoi:10.5170/CERN-2012-003$$hL. Linssen et al.$$mCLIC Conceptual Design Report: Physics and Detectors at CLIC Geneva, Switzerland,, DOI:$$o4$$rCERN-2012-003$$y2012
000070271 999C5 $$01185301$$adoi:10.5170/CERN-2012-005$$hP. Lebrun et al.$$mCLIC Conceptual Design Report: The CLIC Programme: Towards a Staged e+e- Linear Collider Exploring the Terascale Geneva, Switzerland,, DOI:$$o5$$rCERN-2012-005$$y2012
000070271 999C5 $$01124337$$adoi:10.1016/j.physletb.2012.08.020$$cATLAS Collaboration$$hG. Aad et al.$$mDOI:$$o6$$sPhys.Lett.,B716,1$$y2012
000070271 999C5 $$01124338$$adoi:10.1016/j.physletb.2012.08.021$$cCMS Collaboration$$hS. Chatrchyan et al.$$mDOI:$$o7$$sPhys.Lett.,B716,30$$y2012
000070271 999C5 $$01484160$$hH. Abramowicz et al.$$mCLIC Detector and Physics Collaboration, Higgs Physics at the CLIC Electron-Positron Linear Collider, CLICdp-Pub--001, Geneva, Switzerland$$o8$$rarXiv:1608.07538 [hep-ex]$$y2016
000070271 999C5 $$01414262$$hM. Thomson$$o9$$sEur.Phys.J.,C76,2$$y2016
000070271 999C5 $$01392647$$adoi:10.1140/epjc/s10052-016-3911-5$$m72, DOI:$$o9
000070271 999C5 $$hI. Garcia Garcia, M. Vos$$mTop Physics at CLIC, Presentation at the CLICworkshop, CERN, Geneva, Switzerland,, URL:$$o10$$uhttps://indico.cern.ch/event/449801/contributions/1945424/$$y2016
000070271 999C5 $$hH. Abramowicz et al.$$mCLIC Detector and Physics collaboration, Physics at the CLIC e+e- Linear Collider - Input to the Snowmass process,, URL:$$o11$$uhttps://cds.cern.ch/record/1563377$$y2013
000070271 999C5 $$0835665$$hH. Aihara et al.$$mSiD Letter of Intent$$o12$$rSLAC-R-989$$rarXiv:0911.0006 [physics.ins-det]$$y2009
000070271 999C5 $$0851300$$hT. Abe et al.$$mILD Concept Group, The International Large Detector: Letter of Intent, DESY--87, 2010$$o13$$rarXiv:1006.3396 [hep-ex]$$y2009
000070271 999C5 $$01240093$$hT. Behnke et al.$$mThe International Linear Collider Technical Design Report Volume 1: Executive Summary, ILC-Report--040$$o14$$rarXiv:1306.6327 [physics.acc-ph]$$y2013
000070271 999C5 $$0826284$$adoi:10.1016/j.nima.2009.09.009$$hM. A. Thomson$$mDOI:$$o15$$sNucl.Instrum.Meth.,A611,25$$y2009
000070271 999C5 $$01186390$$adoi:10.1016/j.nima.2012.10.038$$hJ. S. Marshall, A. Münnich, M. A. Thomson$$mDOI:$$o16$$sNucl.Instrum.Meth.,A700,153$$y2012
000070271 999C5 $$0759495$$adoi:10.1140/epjc/s10052-011-1742-y.41$$hW. Kilian, T. Ohl, J. Reuter$$mDOI:$$o17$$sEur.Phys.J.,C71,1742$$y2011
000070271 999C5 $$0553138$$hM. Moretti, T. Ohl, J. Reuter$$mO’Mega: An Optimizing Matrix Element Generator, IKDA--06, Darmstadt: Darmstadt TU. Inst. Kernphys.,, arXiv:$$o18$$rhep-ph/0102195$$y2001
000070271 999C5 $$0712925$$adoi:10.1088/1126-6708/2006/05/026$$hT. Sjostrand, S. Mrenna, P. Z. Skands$$mDOI:$$o19$$sJHEP,0605,026$$y2006
000070271 999C5 $$0537385$$adoi:10.1016/S0920-5632(01)01200-2$$hZ. Was$$mDOI:$$o20$$sNucl.Phys.Proc.Suppl.,98,96$$y2001
000070271 999C5 $$0593382$$adoi:10.1016/S0168-9002(03)01368-8$$cGEANT4 Collaboration$$hS. Agostinelli et al.$$mDOI:$$o21$$sNucl.Instrum.Meth.,A506,250$$y2002
000070271 999C5 $$0715388$$adoi:10.1109/TNS.2006.869826$$hJ. Allison et al.$$mDOI:$$o22$$sIEEE Trans.Nucl.Sci.,53,270$$y2006
000070271 999C5 $$0720570$$adoi:10.1016/j.nima.2005.11.138$$hF. Gaede$$mDOI:$$o23$$sNucl.Instrum.Meth.,A559,177$$y2006
000070271 999C5 $$01111557$$adoi:10.1088/1742-6596/331/3/032012$$hN. A. Graf$$morg.lcsim: Event reconstruction in Java, Proc. International Conference on Computing in High Energy and Nuclear Physics (CHEP) Taipei, Taiwan, vol. 331, 2011, p. 032012, DOI:$$o24$$y2010
000070271 999C5 $$0955176$$adoi:10.1140/epjc/s10052-012-1896-2$$hM. Cacciari, G. Salam, G. Soyez$$mDOI:$$o25$$sEur.Phys.J.,C72,1896$$y2012
000070271 999C5 $$0354686$$adoi:10.1016/0550-3213(93)90166-M$$hS. Catani et al.$$mDOI:$$o26$$sNucl.Phys.,B406,187$$y1993
000070271 999C5 $$034969$$adoi:10.1103/PhysRevD.48.3160$$hS. D. Ellis, D. E. Soper$$mDOI:$$o27$$sPhys.Rev.,D48,3160$$y1993
000070271 999C5 $$01380178$$adoi:10.1016/j.nima.2015.11.054$$hT. Suehara, T. Tanabe$$mDOI:$$o28$$sNucl.Instrum.Meth.,A808,109$$y2016
000070271 999C5 $$01302046$$adoi:10.1088/1742-6596/513/3/032077$$hC. Grefe et al.$$mILCDIRAC, a DIRAC extension for the Linear Collider Community, Proc. International Conference on Computing in High Energy and Nuclear Physics (CHEP) Amsterdam, Netherlands, vol. 513, 2014, p. 032077, DOI:$$o29$$y2013
000070271 999C5 $$01315584$$adoi:10.1088/1674-1137/38/9/090001$$hK. A. Olive et al.$$mParticle Data Group DOI:$$o30$$sChin.Phys.,C38,090001$$y2014
000070271 999C5 $$hS. Redford, P. Roloff, M. Vogel$$mPhysics potential of the top Yukawa coupling measurement at a 1.4 TeV Compact Linear Collider using the CLIC SiD detector, CLICdp-Note-001, CERN,, URL:$$o31$$uhttp://cds.cern.ch/record/1690648$$y2014
000070271 999C5 $$01262795$$hS. Dawson et al.$$mWorking Group Report: Higgs Boson, Proc. Community Summer Study: Snowmass on the Mississippi (CSS) Minneapolis, MN, USA$$o32$$rarXiv:1310.8361 [hep-ex]$$y2013
000070271 999C5 $$01377203$$hK. Fujii et al.$$mPhysics Case for the International Linear Collider, ILC-Note--067$$o33$$rarXiv:1506.05992 [hep-ex]$$y2015
000070271 999C5 $$hF. Simon, M. Szalay, P. Roloff$$mCombined Fits of CLIC Higgs Results for the Snowmass Process, LCD-Note--012,, URL:$$o34$$uhttps://cds.cern.ch/record/1603687$$y2013
000070271 999C5 $$01084695$$adoi:10.5170/CERN-2012-002$$hS. Dittmaier et al.$$mHandbook of LHC Higgs Cross Sections: 2. Differential Distributions DOI:$$o35$$rCERN-2012-002$$y2012
000070271 999C5 $$01118454$$adoi:10.1103/PhysRevD.86.095001$$hR. S. Gupta, H. Rzehak, J. D. Wells$$mDOI: 42$$o36$$sPhys.Rev.,D86,095001$$y2012
000070271 999C5 $$01235727$$adoi:10.1103/PhysRevD.88.055024$$hR. S. Gupta, H. Rzehak, J. D. Wells$$mDOI:$$o37$$sPhys.Rev.,D88,055024$$y2013
000070271 999C5 $$01356276$$adoi:10.1103/PhysRevLett.114.191803$$cCMS Collaborations$$hG. Aad et al.$$mATLAS DOI:$$o38$$sPhys.Rev.Lett.,114,191803$$y2015
000070271 999C5 $$01286320$$cD0 Collaborations$$mATLAS, CDF, CMS First combination of Tevatron and LHC measurements of the top-quark mass$$o39$$rarXiv:1403.4427 [hep-ex]$$y2014
000070271 999C5 $$01322367$$cATLAS Collaboration$$hG. Aad et al.$$o40$$sEur.Phys.J.,C75,7$$y2015
000070271 999C5 $$01353391$$adoi:10.1140/epjc/s10052-015-3544-0$$m330, DOI:$$o40
000070271 999C5 $$01468064$$cATLAS Collaboration$$hM. Aaboud et al.$$mMeasurement of the top quark mass in the t¯t → dilepton channel from √ s = 8 TeV ATLAS data, CERN-EP--114$$o41$$rarXiv:1606.02179 [hep-ex]$$y2016
000070271 999C5 $$01393269$$adoi:10.1103/PhysRevD.93.072004$$cCMS Collaboration$$hV. Khachatryan et al.$$m072004, DOI:$$o42$$sPhys.Rev.,D93,7$$y2016
000070271 999C5 $$01116539$$adoi:10.1007/JHEP08(2012)098$$hG. Degrassi et al.$$mDOI:$$o43$$sJHEP,1208,098$$y2012
000070271 999C5 $$01242456$$adoi:10.1007/JHEP12(2013)089$$hD. Buttazzo et al.$$mDOI:$$o44$$sJHEP,1312,089$$y2013
000070271 999C5 $$01263763$$hK. Agashe et al.$$mTop Quark Working Group, Working Group Report: Top Quark, Proc. Community Summer Study: Snowmass on the Mississippi (CSS) Minneapolis, MN, USA$$o45$$rarXiv:1311.2028 [hep-ph]$$y2013
000070271 999C5 $$01452688$$hM. Vos et al.$$mTop physics at high-energy lepton colliders, IFIC-16-12$$o46$$rarXiv:1604.08122 [hep-ex]$$y2016
000070271 999C5 $$01223994$$adoi:10.1140/epjc/s10052-013-2530-7$$hK. Seidel et al.$$m2530, DOI:$$o47$$sEur.Phys.J.,C73,8$$y2013
000070271 999C5 $$01377594$$adoi:10.1103/PhysRevLett.115.192001$$hM. Beneke et al.$$m192001, DOI:$$o48$$sPhys.Rev.Lett.,115,19$$y2015
000070271 999C5 $$01427722$$hF. Simon, A First Look$$mat the Impact of NNNLO Theory Uncertainties on Top Mass Measurements at the ILC, Proc. International Workshop on Future Linear Colliders (LCWS15) Whistler, B.C Canada$$o49$$rarXiv:1603.04764 [hep-ex]$$y2016
000070271 999C5 $$01342942$$adoi:10.1103/PhysRevLett.114.142002$$hP. Marquard et al.$$m142002, DOI:$$o50$$sPhys.Rev.Lett.,114,14$$y2015
000070271 999C5 $$01245251$$hM. S. Amjad et al.$$mA precise determination of top quark electro-weak couplings at the ILC operating at √ s = 500 GeV, IFIC-13-06$$o51$$rarXiv:1307.8102 [hep-ex]$$y2013
000070271 999C5 $$0665879$$adoi:10.1103/PhysRevD.71.054013$$hU. Baur et al.$$mPhys. Rev. D 71 (5) 054013, DOI:$$o52$$y2005
000070271 999C5 $$0700947$$adoi:10.1103/PhysRevD.73.034016$$hU. Baur et al.$$mPhys. Rev. D 73 (3) 034016, DOI:$$o53$$y2006
000070271 999C5 $$01091081$$hP. Doublet et al.$$mDetermination of Top-quark Asymmetries at the ILC$$o54$$rarXiv:1202.6659 [hep-ex]$$y2012
000070271 999C5 $$01319310$$hM. S. Amjad et al.$$o55$$sEur.Phys.J.,C75,10$$y2015
000070271 999C5 $$01372604$$adoi:10.1140/epjc/s10052-015-3746-5$$m512, DOI:$$o55
000070271 999C5 $$01285486$$hF. Richard$$mPresent and future constraints on top EW couplings, LAL-ORSAY-14-55 43$$o56$$rarXiv:1403.2893 [hep-ph]$$y2014
000070271 999C5 $$01347266$$adoi:10.1007/JHEP04(2015)182$$hP. Janot$$mDOI:$$o57$$sJHEP,1504,182$$y2015
000070271 999C5 $$01255676$$adoi:10.1007/JHEP02(2014)006$$hR. Contino et al.$$mDOI:$$o58$$sJHEP,1402,006$$y2014
000070271 999C5 $$hL. Weuste, F. Simon$$mMass and Cross Section Measurements of light-flavored Squarks at CLIC, LCD-Note--027,, URL:$$o59$$uhttps://cds.cern.ch/record/1499132$$y2011
000070271 999C5 $$hT. Barklow, A. Münnich, P. Roloff$$mMeasurement of chargino and neutralino pair production at CLIC, LCD-Note--037, 2012, URL:$$o60$$uhttps://cds.cern.ch/record/1443499$$y2011
000070271 999C5 $$01123670$$adoi:10.1007/JHEP01(2013)019$$hR. Srivastava, S. Vaidya$$mDOI:$$o61$$sJHEP,1301,019$$y2013
000070271 999C5 $$hJ.-J. Blaising, J. D. Wells$$mPhysics performances for Z’ searches at 3 TeV and 1.5 TeV CLIC, LCD-Note--009,, URL:$$o62$$uhttps://cds.cern.ch/record/1471941$$y2012
000070271 999C5 $$01475013$$hC. Fleper et al.$$mScattering of W and Z Bosons at High-Energy Lepton Colliders$$o63$$rDESY-16-098$$rarXiv:1607.03030 [hep-ph]$$y2016
000070271 999C5 $$01322367$$hT. Price et al.$$o64$$sEur.Phys.J.,C75,7$$y2015
000070271 999C5 $$01318942$$adoi:10.1140/epjc/s10052-015-3532-4$$m309, DOI:$$o64
000070271 999C5 $$hK. N. Sjobak, A. Grudiev, E. Adli$$mNew Criterion for Shape Optimization of Normal-Conducting Accelerator Cells for High-Gradient Applications, Proc. 27th Linear Accelerator Conference (LINAC) Geneva, Switzerland,, p. MOPP028, URL:$$o65$$uhttp://jacow.org/LINAC2014/papers/mopp028.pdf$$y2014
000070271 999C5 $$hK. N. Sjobak$$mto be published, PhD thesis, University of Oslo$$o66$$y2016
000070271 999C5 $$9CURATOR$$hA. Degiovanni et al.$$mHigh-Gradient test results from a CLIC prototype accelerating structure: TD26CC$$o67$$rCERN-ACC-2014-0147$$uhttp://cds.cern.ch/record/1742280$$y2014
000070271 999C5 $$9CURATOR$$hH. Zha, A. Grudiev$$mNew CLIC_G structure design, CERN, Geneva, Switzerland$$o68$$rCERN-ACC-2016-0066$$uhttp://cds.cern.ch/record/2157079$$y2016
000070271 999C5 $$01455704$$adoi:10.1103/PhysRevAccelBeams.19.032001$$hA. Degiovanni, W. Wuensch, J. Giner Navarro$$mPhys. Rev. Accel. Beams 19 (3) 032001, DOI:$$o69$$y2016
000070271 999C5 $$9CURATOR$$hB. Jeanneret$$mCLIC Total Electrical power: a parametrization$$o70$$rCERN-ACC-Note-2013-0020$$uhttp://cds.cern.ch/record/1599195$$y2013
000070271 999C5 $$hK.N. Sjobak, A. Grudiev$$mThe CLICopti RF structure parameter estimator CERN, Geneva, Switzerland,, URL:$$o71$$rCERN-OPEN-2014-036$$uhttp://cds.cern.ch/record/1712948$$y2014
000070271 999C5 $$hB. Shepherd et al.$$mT11006, URL:$$o72$$sJINST,9,11$$uhttp://stacks.iop.org/1748-0221/9/i=11/a=T11006$$y2014
000070271 999C5 $$hI. Syratchev$$mHigh Efficiency International Klystron Activity, Towards high power klystrons with RF power conversion efficiency in the order of 90%, Presentation at the ECFA LCworkshop, Santander, Spain,, URL:$$o73$$uhttps://agenda.linearcollider.org/event/7014/contributions/36949/$$y2016
000070271 999C5 $$0869381$$hP. Lebrun, P. Garbincius$$mAssessing Risk in Costing High-energy Accelerators: from Existing Projects to the Future Linear Collider, Proc. 1st International Particle Accelerator Conference (IPAC’10) Kyoto, Japan, vol. C100523,, p. WEPE021 44$$o74$$rarXiv:1207.4994 [physics.acc-ph]$$y2010
000070271 999C5 $$0100628$$adoi:10.1109/TNS.1975.4327871$$hZ. D. Farkas et al.$$mIEEE Trans. Nucl. Sci. 22 1299, DOI:$$o75$$rSLAC-PUB-1561$$y1975
000070271 999C5 $$adoi:10.1109/TED.2015.2464096$$hA. Baikov, C. Marrelli, I. Syratchev$$m3406, URL:$$o76$$sIEEE Trans.Electron.Dev.,62,10$$y2015
000070271 999C5 $$hP. Wang et al.$$mMulti-stage pulse compressor, Presentation at the CLICworkshop, CERN, Geneva, Switzerland,, URL: 45$$o77$$uhttps://indico.cern.ch/event/449801/contributions/1945389/$$y2016