002799799 001__ 2799799
002799799 003__ SzGeCERN
002799799 005__ 20220120141806.0
002799799 0247_ $$2DOI$$9IEEE$$a10.1109/IVEC45766.2020.9520585
002799799 0248_ $$aoai:cds.cern.ch:2799799$$pcerncds:CERN
002799799 035__ $$9https://inspirehep.net/api/oai2d$$aoai:inspirehep.net:1944435$$d2022-01-17T14:51:04Z$$h2022-01-18T05:00:45Z$$mmarcxml
002799799 035__ $$9Inspire$$a1944435
002799799 041__ $$aeng
002799799 100__ $$aCai, Jinchi$$uLancaster U.$$uCERN$$vCERN, Geneva, Meyrin, Switzerland
002799799 245__ $$9IEEE$$aDesign Study of X-band High Efficiency Klystrons for CLIC
002799799 260__ $$c2020
002799799 300__ $$a2 p
002799799 520__ $$9IEEE$$aThe design of two X-band high efficiency (HE) Klystrons are presented in this paper. Based on Core Oscillation Method (COM) and coupled-cell output structure topology, 8MW Klystron for Xbox test stand can yield 58% output efficiency with beam perveance of 1.6uP. Scaling and post-optimization method is used for 50MW Klystron for CLIC accelerating structures design, which can provide 65% output efficiency with beam perveance of 0.75 uP. The peak electric field is lower than 100kV/mm for both cases, which is purposely optimized to avoid RF breakdown. The parameter optimization is done with KlyC1.5D simulation and results are verified by CST PIC simulations.
002799799 542__ $$3publication$$dIEEE$$g2020
002799799 65017 $$2SzGeCERN$$aAccelerators and Storage Rings
002799799 6531_ $$9author$$aHigh efficiency Klystrons
002799799 6531_ $$9author$$aCore-oscillation method
002799799 6531_ $$9author$$aCoupled-cell structures
002799799 690C_ $$aARTICLE
002799799 690C_ $$aCERN
002799799 693__ $$sCLIC
002799799 700__ $$aSyratchev, Igor$$uCERN
002799799 773__ $$c121-122$$wC20-10-19.5$$y2020
002799799 960__ $$a13
002799799 962__ $$b2799742$$k121-122$$nonline20201019
002799799 980__ $$aARTICLE
002799799 980__ $$aConferencePaper