CERN Accelerating science

002665488 001__ 2665488
002665488 003__ SzGeCERN
002665488 005__ 20220810142754.0
002665488 0247_ $$2DOI$$9submitter$$a10.1016/j.nima.2018.02.044
002665488 0248_ $$aoai:inspirehep.net:1656524$$pcerncds:CERN:FULLTEXT$$pcerncds:FULLTEXT$$pcerncds:CERN$$qINSPIRE:HEP$$qForCDS
002665488 035__ $$9http://inspirehep.net/oai2d$$aoai:inspirehep.net:1656524$$d2019-03-04T09:43:40Z$$h2019-03-05T05:00:13Z$$mmarcxml
002665488 035__ $$9Inspire$$a1656524
002665488 041__ $$aeng
002665488 100__ $$aPepitone, K$$kORCID:0000-0002-4514-293X$$memail:[email protected]$$uCERN
002665488 245__ $$9Elsevier$$aThe electron accelerators for the AWAKE experiment at CERN - Baseline and future developments
002665488 246__ $$9crossref$$aThe electron accelerators for the AWAKE experiment at CERN—Baseline and Future Developments
002665488 260__ $$c2018
002665488 300__ $$a5 p
002665488 520__ $$9submitter$$aThe AWAKE collaboration prepares a proton driven plasma wakefield acceleration experiment using the SPS beam at CERN. A long proton bunch extracted from the SPS interacts with a high power laser and a 10 m long rubidium vapor plasma cell to create strong wakefields allowing sustained electron acceleration. The electron beam to probe these wakefields is created by an electron accelerator consisting of an rf-gun and a booster structure. This electron source should provide beams with intensities between 0.1 and 1 nC, bunch lengths between 0.3 and 3 ps and an emittance of the order of 2 mm mrad. The booster structure should accelerate the electrons to 16 MeV. The electron line includes a series of diagnostics (pepper-pot, BPMs, spectrometer, Faraday cup and screens) and an optical transfer line merges the electron beam with the proton beam on the same axis. The installation of the electron line started in early 2017 and the commissioning will take place at the end of 2017. The first phase of operation is called RUN1. After the long shutdown of LHC a second phase for AWAKE is planned starting 2021 called RUN2. In this phase the aim is to demonstrate the acceleration of high quality electron beams therefore a bunch length of the order of 100 fs rms is required corresponding to a fraction of the plasma wavelength. The AWAKE collaboration is studying the design of such an injector either based on classical rf-gun injectors or on laser wake-field acceleration. The focus for the RF accelerator is on a hybrid design using an S-band rf-gun and x-band bunching and acceleration cavities. The layout of the current and the future electron accelerator and transfer line, including the diagnostics will be presented.
002665488 520__ $$9Elsevier$$aThe AWAKE collaboration prepares a proton driven plasma wakefield acceleration experiment using the SPS beam at CERN. A long proton bunch extracted from the SPS interacts with a high power laser and a 10 m long rubidium vapor plasma cell to create strong wakefields allowing sustained electron acceleration. The electron beam to probe these wakefields is created by an electron accelerator consisting of an rf-gun and a booster structure. This electron source should provide beams with intensities between 0.1 and 1 nC, bunch lengths between 0.3 and 3 ps and an emittance of the order of 2 mm mrad. The booster structure should accelerate the electrons to 16 MeV. The electron line includes a series of diagnostics (pepper-pot, BPMs, spectrometer, Faraday cup and screens) and an optical transfer line merges the electron beam with the proton beam on the same axis. The installation of the electron line started in early 2017 and the commissioning will take place at the end of 2017. The first phase of operation is called RUN1. After the long shutdown of LHC a second phase for AWAKE is planned starting 2021 called RUN2. In this phase the aim is to demonstrate the acceleration of high quality electron beams therefore a bunch length of the order of 100 fs rms is required corresponding to a fraction of the plasma wavelength. The AWAKE collaboration is studying the design of such an injector either based on classical rf-gun injectors or on laser wake-field acceleration. The focus for the RF accelerator is on a hybrid design using an S-band rf-gun and x-band bunching and acceleration cavities. The layout of the current and the future electron accelerator and transfer line, including the diagnostics will be presented.
002665488 540__ $$3publication$$aCC-BY-4.0
002665488 540__ $$3publication$$bElsevier$$uhttp://creativecommons.org/licenses/by/4.0/
002665488 542__ $$3publication$$f© 2018 The Authors
002665488 65017 $$2SzGeCERN$$aAccelerators and Storage Rings
002665488 6531_ $$9author$$aElectron gun
002665488 6531_ $$9author$$aAccelerators
002665488 6531_ $$9author$$aCharged particle beams in accelerators
002665488 6531_ $$9author$$aDiagnostics
002665488 690C_ $$aCERN
002665488 693__ $$aCERN SPS$$eAWAKE
002665488 700__ $$aDoebert, S$$kORCID:0000-0002-8053-2466$$memail:[email protected]$$uCERN
002665488 700__ $$aApsimon, [email protected]$$uLancaster U.
002665488 700__ $$aBauche, J$$uCERN
002665488 700__ $$aBernardini, M$$uCERN
002665488 700__ $$aBracco, C$$uCERN
002665488 700__ $$aBurt, G$$uLancaster U.
002665488 700__ $$aChauchet, A$$uCERN
002665488 700__ $$aChevallay, E$$uCERN
002665488 700__ $$aChritin, N$$uCERN
002665488 700__ $$aCurt, S$$uCERN
002665488 700__ $$aDamerau, H$$uCERN
002665488 700__ $$aDayyani Kelisani, M$$uCERN
002665488 700__ $$aDelory, C$$uCERN
002665488 700__ $$aFedosseev, V$$uCERN
002665488 700__ $$aFriebel, F$$uCERN
002665488 700__ $$aGalleazzi, F$$uCERN
002665488 700__ $$aGorgisyan, I$$uCERN
002665488 700__ $$aGschwendtner, E$$uCERN
002665488 700__ $$aHansen, J$$uCERN
002665488 700__ $$aJensen, L$$uCERN
002665488 700__ $$aKeeble, F$$uUniversity Coll. London
002665488 700__ $$aMaricalva, L$$uCERN
002665488 700__ $$aMazzoni, S$$uCERN
002665488 700__ $$aMcMonagle, G$$uCERN
002665488 700__ $$aMete, O$$uManchester U.
002665488 700__ $$aPardons, A$$uCERN
002665488 700__ $$aPasquino, C$$uCERN
002665488 700__ $$aVerzilov, V$$uTRIUMF
002665488 700__ $$aSchmidt, J S$$uCERN
002665488 700__ $$aSoby, L$$uCERN
002665488 700__ $$aWilliamson, B$$uManchester U.
002665488 700__ $$aYamakawa, E$$uLancaster U.
002665488 700__ $$aPitman, S$$uLancaster U.
002665488 700__ $$aMitchell, J$$uLancaster U.
002665488 773__ $$c102-106$$pNucl. Instrum. Methods Phys. Res., A$$v909$$wC17-09-24.3$$y2018
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002665488 999C5 $$01614082$$hA. Caldwell, et al.$$mAWAKE Design Report: A Proton-Driven Plasma Wakefield Acceleration Experiment at CERN, Internal Note$$o1$$rCERN-SPSC-2013-013$$y2013
002665488 999C5 $$01614355$$hP. Muggli, et al.$$mAWAKE readiness for the study of the seeded self-modulation of a 400 GeV proton bunch, in: Plasma Physics Conference, Belfast, Northern Ireland$$o2$$rarXiv:1708.01087$$y2017
002665488 999C5 $$9CURATOR$$hG. Geschonke, et al.$$mCTF3 Design Report, Tech. Rep., CERN, Geneva$$o3$$rCTF3-Note-2002-047$$y2002
002665488 999C5 $$01091133$$hO. Mete, et al.$$mProduction of long bunch trains with 4.5 uC total charge using a photoinjector$$o4$$sPhys.Rev.ST Accel.Beams,15,022803$$y2012
002665488 999C5 $$hA. Petrenko, et al.$$mElectron injection studies for the AWAKE experiment, in: IPAC, Dresden, Germany,, pp. TUPME078$$o5$$y2014
002665488 999C5 $$9CURATOR$$hK. Pepitone, et al.$$mThe electron accelerator for the awake experiment at cern Nucl. Instrum. Methods Phys. Sect. A 829  Supplement C pp. 73-75 2nd European Advanced Accelerator Concepts Workshop - EAAC 2015$$o6$$sNucl.Instrum.Meth.,A829,73-75$$y2016
002665488 999C5 $$9CURATOR$$hR. Roux, et al.$$mDesign of a RF Photo-gun$$o7$$rCARE-Note-2004-034$$y2004
002665488 999C5 $$9CURATOR$$hE. Chevallay$$mExperimental Results at the CERN Photoemission Laboratory with Co-deposition Photocathodes in the Frame of the CLIC Studies, Internal Note$$o8$$rCTF3-Note-2012-104$$y2012
002665488 999C5 $$hO. Mete, et al.$$mModeling of an electron injector for the AWAKE project, in: IPAC, Richmond, USA,, pp. TUPJE059$$o9$$y2015
002665488 999C5 $$hJ.S. Schmidt, et al.$$mThe AWAKE electron primary beam line, in: IPAC, Richmond, USA,, pp. WEPWA039$$o10$$y2015
002665488 999C5 $$hA. Caldwell, et al.$$mPath to awake: Evolution of the concept Nucl. Instrum. Methods Phys. Sect. A 829  Supplement C pp. 3-16 2nd European Advanced Accelerator Concepts Workshop - EAAC$$o11$$y2015
002665488 999C5 $$hV. Minakov, et al.$$mEmittance of the accelerated electron bunch in two-stage awake scenario, in: These NIM Proceedings, EAAC, Elba, Italy$$o12$$y2017
002665488 999C5 $$hA. Petrenko, et al.$$mSimulations of the possible awake run-2 experiment at cern, in: These NIM Proceedings, EAAC, Elba, Italy$$o13$$y2017
002665488 999C5 $$hB. Williason, et al.$$mA laser-wakefield accelerator as the electron injector for the awake experiment, in: These NIM Proceedings, EAAC, Elba, Italy$$o14$$y2017
002665488 999C6 $$a0-0-0-1-0-0-1$$t2018-02-20 12:01:02$$vInvenio/1.1.2.1260-aa76f refextract/1.5.44