Multi-Physics Analysis of CW Superconducting Cavity for the LCLS-II using ACE3P

Li, Zenghai; Adolphsen, Chris; Kononenko, Oleksiy; Raubenheimer, Tor; Rivetta, Claudio; Ross, Marc; Xiao, Liling

doi:10.18429/JACoW-IPAC2014-WEPRI067

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RIS citation export for WEPRI067: Multi-Physics Analysis of CW Superconducting Cavity for the LCLS-II using ACE3P

TY - CONF
AU - Li, Z.
AU - Adolphsen, C.
AU - Kononenko, O.
AU - Raubenheimer, T.O.
AU - Rivetta, C.H.
AU - Ross, M.C.
AU - Xiao, L.
ED - Petit-Jean-Genaz, Christine
ED - Arduini, Gianluigi
ED - Michel, Peter
ED - Schaa, Volker RW
TI - Multi-Physics Analysis of CW Superconducting Cavity for the LCLS-II using ACE3P
J2 - Proc. of IPAC2014, Dresden, Germany, June 15-20, 2014
C1 - Dresden, Germany
T2 - International Particle Accelerator Conference
T3 - 5
LA - english
AB - The LCLS-II linac utilizes superconducting technology operating at continuous wave to accelerate the 1-MHz electron beams to 4 GeV to produce tunable FELs. The TESLA 9-cell superconducting cavity is adopted as the baseline design for the linac. The design gradient is approximately 16 MV/m. The highest operating current is 300 μA. Assuming that the RF power is matched at the highest current, the optimal loaded QL of the cavity is found to be around 4·10⁷. Because of the high QL, the cavity bandwidth approaches the background microphonic detuning, and the performance of the cavity is tightly coupled to the mechanical perturbations of the cavity/cryomodule system. The resulting large phase and amplitude variations in the cavity require active feedback to achieve the 0.01% amplitude and phase stability requirements. To understand the cavity RF response and feedback requirements to the microphonics and Lorentz Force detuning, we have developed a simulation model of the RF-mechanical coupled system using parameters obtained with the multi-physics solver ACE3P. We will present the simulation results of the LCLS-II linac under different power feed scenarios and feedback schemes.
PB - JACoW
CP - Geneva, Switzerland
SP - 2645
EP - 2647
KW - cavity
KW - simulation
KW - feedback
KW - operation
KW - vacuum
DA - 2014/07
PY - 2014
SN - 978-3-95450-132-8
DO - 10.18429/JACoW-IPAC2014-WEPRI067
UR - http://jacow.org/ipac2014/papers/wepri067.pdf
ER -