001019366 001__ 1019366
001019366 005__ 20260115203944.0
001019366 0247_ $$2doi$$a10.18429/JACOW-IPAC2023-TUPA194
001019366 037__ $$aFZJ-2023-05336
001019366 041__ $$aen-us
001019366 1001_ $$0P:(DE-HGF)0$$aForck, Peter$$b0
001019366 1112_ $$a14th International Particle Accelerator Conference$$cVenice$$d2023-05-07 - 2023-05-12$$gIPAC23$$wItaly
001019366 245__ $$aRF-acceleration studies for the HBS-linac applying alternating phase focusing concepts
001019366 260__ $$bJACoW Publishing$$c2023
001019366 300__ $$a1768-1771
001019366 3367_ $$2ORCID$$aCONFERENCE_PAPER
001019366 3367_ $$033$$2EndNote$$aConference Paper
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001019366 3367_ $$0PUB:(DE-HGF)8$$2PUB:(DE-HGF)$$aContribution to a conference proceedings$$bcontrib$$mcontrib$$s1768471929_18055
001019366 520__ $$aThe recent layout of the Jülich High Brilliance Neutron Source (HBS) driver linac is based on short crossbar H-mode (CH) cavities operated at a fixed synchronous phase. In the last decades the computing power for the development of linacs, available to physicists and engineers, has been increased drastically. This also enabled the accelerator community to finally carry out the required R&D to generate further the idea of drift tube linacs with alternating phase focusing (APF) beam dynamics, originally proposed in the 1950s. This focusing method uses the electric fields in between the drift tubes (i.e., gaps) to provide subsequent transverse and longitudinal focusing to the beam along multiple gaps. The beam focusing properties within each gap are adjusted individually by means of the synchronous phase. As a result of the alternating phase focusing method, these linacs can operate completely without internal magnetic lenses. The R&D-program for the high brilliance neutron source HBS offered the opportunity to investigate the APF concept further in order to open this advanced concept for high duty-factor, high intensity hadron beam acceleration. Besides, a prototype APF-interdigital H-mode (IH)-cavity has been designed and is going to be build and tested in the next future.
001019366 536__ $$0G:(DE-HGF)POF4-6G4$$a6G4 - Jülich Centre for Neutron Research (JCNS) (FZJ) (POF4-6G4)$$cPOF4-6G4$$fPOF IV$$x0
001019366 536__ $$0G:(DE-HGF)POF4-632$$a632 - Materials – Quantum, Complex and Functional Materials (POF4-632)$$cPOF4-632$$fPOF IV$$x1
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001019366 650_7 $$2Other$$aAccelerator Physics
001019366 650_7 $$2Other$$amc4-hadron-accelerators - MC4: Hadron Accelerators
001019366 650_7 $$2Other$$amc4-a08-linear-accelerators - MC4.A08: Linear Accelerators
001019366 65027 $$0V:(DE-MLZ)SciArea-220$$2V:(DE-HGF)$$aInstrument and Method Development$$x0
001019366 65017 $$0V:(DE-MLZ)GC-2002-2016$$2V:(DE-HGF)$$aInstrument and Method Development$$x0
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001019366 7001_ $$0P:(DE-HGF)0$$aGettmann, Viktor$$b1
001019366 7001_ $$0P:(DE-HGF)0$$aBurandt, Christoph$$b2
001019366 7001_ $$aList, Julian$$b3
001019366 7001_ $$0P:(DE-HGF)0$$aLauber, Simon$$b4$$eCorresponding author
001019366 7001_ $$0P:(DE-Juel1)168124$$aGutberlet, Thomas$$b5
001019366 7001_ $$aMiski-Oglu, Maksym$$b6
001019366 7001_ $$aKuerzeder, Thorsten$$b7
001019366 7001_ $$aBarth, Winfried$$b8
001019366 7001_ $$aBasten, Markus$$b9
001019366 7001_ $$aSchwarz, Malte$$b10
001019366 7001_ $$aDroba, Martin$$b11
001019366 7001_ $$aDziuba, Florian$$b12
001019366 7001_ $$aYaramyshev, Stepan$$b13
001019366 7001_ $$aPodlech, Holger$$b14
001019366 7001_ $$aAssmann, Ralph$$b15$$eEditor
001019366 7001_ $$aMcIntosh, Peter$$b16$$eEditor
001019366 7001_ $$aFabris, Alessandro$$b17$$eEditor
001019366 7001_ $$aBisoffi, Giovanni$$b18$$eEditor
001019366 7001_ $$aAndrian, Ivan$$b19$$eEditor
001019366 7001_ $$aVinicola, Giulia$$b20$$eEditor
001019366 773__ $$a10.18429/JACOW-IPAC2023-TUPA194
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