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Grudiev, A.

Paper Title Page
WEPMN070 High Power Test of an X-band Slotted-Iris Accelerator Structure at NLCTA 2191
 
  • S. Doebert, R. Fandos, A. Grudiev, S. T. Heikkinen, J. A. Rodriguez, M. Taborelli, W. Wuensch
    CERN, Geneva
  • C. Adolphsen, L. Laurent
    SLAC, Menlo Park, California
 
  The CLIC study group at CERN has built two X-band HDS (Hybrid Damped Structure) accelerating structures for high-power testing in NLCTA at SLAC. These accelerating structures are novel with respect to their rf-design and their fabrication technique. The eleven-cell constant impedance structures, one made out of copper and one out of molybdenum, are assembled from clamped high-speed milled quadrants. They feature the same heavy higher-order-mode damping as nominal CLIC structures achieved by slotted irises and radial damping waveguides for each cell. The X-band accelerators are exactly scaled versions of structures tested at 30 GHz in the CLIC test facility, CTF3. The results of the X-band tests are presented and compared to those at 30 GHz to determine frequency scaling, and are compared to the extensive copper data from the NLC structure development program to determine material dependence and make a basic validation of the HDS design.  
FROBC01 30 GHz High-Gradient Accelerating Structure Test Results 3818
 
  • J. A. Rodriguez, G. Arnau-Izquierdo, R. Corsini, S. Doebert, R. Fandos, A. Grudiev, I. Syratchev, M. Taborelli, F. Tecker, P. Urschutz, W. Wuensch
    CERN, Geneva
  • H. Aksakal, Z. Nergiz
    Ankara University, Faculty of Sciences, Tandogan/Ankara
  • M. Johnson
    UU/ISV, Uppsala
  • O. M. Mete
    Ankara University, Faculty of Engineering, Tandogan, Ankara
 
  The CLIC study is high power testing accelerating structures in a number of different materials and accelerating structure designs to understand the physics of breakdown, determine the appropriate scaling of performance and in particular to find ways to increase achievable accelerating gradient. The most recent 30 GHz structures which have been tested include damped structures in copper, molybdenum, titanium and aluminum. The results from these new structures are presented and compared to previous ones to determine dependencies of quantities such as achievable accelerating gradient, pulse length, power flow, conditioning rate and breakdown rate.  
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