• G. Burt
  
• C. D. Beard, P. Goudket, P. A. McIntosh
  STFC/DL/ASTeC, Daresbury, Warrington, Cheshire
• L. Bellantoni
  Fermilab, Batavia, Illinois
• R. G. Carter, A. C. Dexter, R. O. Jenkins
  Cockcroft Institute, Lancaster University, Lancaster

The ILC crab cavity will require the design of an appropriate power coupler. The beamloading in dipole cavities is considerably more variable than accelerating cavities, hence simulations have been performed to establish the required external Q. Simulations of a suitable coupler were then performed and were verified using a normal conducting prototype with variable coupler tips.

• E. R. Harms
  
• T. T. Arkan, L. Bellantoni, H. Carter, H. Edwards, M. Foley, T. N. Khabiboulline, D. V. Mitchell, D. R. Olis, A. M. Rowe, N. Solyak
  Fermilab, Batavia, Illinois

Fermilab is involved in an effort to assemble 3.9 GHz superconducting RF cavities into a four cavity cryomodule for use at the DESY TTF/FLASH facility as a third harmonic structure. The design gradient of these cavities is 14 MV/m limited by thermal heat transfer. This effort involves design, fabrication, intermediate testing, assembly, and eventual delivery of the cryomodule. We report on all facets of this enterprise from design through future plans. Included will be test results of single 9-cell cavities, lessons learned, and current status.

• D. F. Orris
  
• L. Bellantoni, R. H. Carcagno, H. Edwards, E. R. Harms, T. N. Khabiboulline, S. Kotelnikov, A. Makulski, R. Nehring, Y. M. Pischalnikov
  Fermilab, Batavia, Illinois

Fast readout of strategically placed low heat capacity thermometry can provide valuable information of Superconducting RF (SRF) cavity performance. Such a system has proven very effective for the development and testing of new cavity designs. Recently, several RTDs were installed in key regions of interest on a new 9 cell 3.9 GHz SRF cavity with integrated HOM design at FNAL. A data acquisition system was developed to read out these sensors with enough time and temperature resolution to measure temperature changes on the cavity due to heat generated from multipacting or quenching within power pulses. The design and performance of this fast thermometry system will be discussed along with results from tests of the 9 cell 3.9GHz SRF cavity.

• L. Xiao
  
• L. Bellantoni
  Fermilab, Batavia, Illinois
• G. Burt
  Cockcroft Institute, Lancaster University, Lancaster
• P. Goudket, P. A. McIntosh
  STFC/DL/ASTeC, Daresbury, Warrington, Cheshire
• K. Ko, Z. Li, C.-K. Ng, G. L. Schussman, A. Seryi, R. Uplenchwar
  SLAC, Menlo Park, California

The FNAL 9-cell 3.9GHz deflecting cavity designed for the CKM experiment was chosen as the baseline design for the ILC BDS crab cavity. Effective damping is required for the lower-order TM01 modes (LOM), the same-order TM11 modes (SOM) as well as the HOM modes to minimize the beam loading and beam centroid steering due to wakefields. Simulation results of the original CKM design using the eigensolver Omega3P showed that both the notch filters of the HOM/LOM couplers are very sensitive to the notch gap, and the damping of the unwanted modes is suboptimal for the ILC. To meet the ILC requirements, the couplers were redesigned to improve the damping and tuning sensitivity. With the new design, the damping of the LOM/SOM/HOM modes is significantly improved, the sensitivity of the notch filter for the HOM coupler is reduced by one order of magnitude and appears mechanically feasible, and the LOM coupler is simplified by aligning it on the same plane as the SOM coupler and by eliminating the notch filter. In this paper, we will present the coupler optimization and tolerance studies for the crab cavity.

• A. Seryi
  
• I. V. Agapov, G. A. Blair, S. T. Boogert, J. Carter
  Royal Holloway, University of London, Surrey
• M. Alabau, P. Bambade, J. Brossard, O. Dadoun
  LAL, Orsay
• J. A. Amann, R. Arnold, F. Asiri, K. L.F. Bane, P. Bellomo, E. Doyle, A. F. Fasso, L. Keller, J. Kim, K. Ko, Z. Li, T. W. Markiewicz, T. V.M. Maruyama, K. C. Moffeit, S. Molloy, Y. Nosochkov, N. Phinney, T. O. Raubenheimer, S. Seletskiy, S. Smith, C. M. Spencer, P. Tenenbaum, D. R. Walz, G. R. White, M. Woodley, M. Woods, L. Xiao
  SLAC, Menlo Park, California
• M. Anerella, A. K. Jain, A. Marone, B. Parker
  BNL, Upton, Long Island, New York
• D. A.-K. Angal-Kalinin, C. D. Beard, J.-L. Fernandez-Hernando, P. Goudket, F. Jackson, J. K. Jones, A. Kalinin, P. A. McIntosh
  STFC/DL/ASTeC, Daresbury, Warrington, Cheshire
• R. Appleby
  UMAN, Manchester
• J. L. Baldy, D. Schulte
  CERN, Geneva
• L. Bellantoni, A. I. Drozhdin, V. S. Kashikhin, V. Kuchler, T. Lackowski, N. V. Mokhov, N. Nakao, T. Peterson, M. C. Ross, S. I. Striganov, J. C. Tompkins, M. Wendt, X. Yang
  Fermilab, Batavia, Illinois
• K. Buesser
  DESY, Hamburg
• P. Burrows, G. B. Christian, C. I. Clarke, A. F. Hartin
  OXFORDphysics, Oxford, Oxon
• G. Burt, A. C. Dexter
  Cockcroft Institute, Warrington, Cheshire
• J. Carwardine, C. W. Saunders
  ANL, Argonne, Illinois
• B. Constance, H. Dabiri Khah, C. Perry, C. Swinson
  JAI, Oxford
• O. Delferriere, O. Napoly, J. Payet, D. Uriot
  CEA, Gif-sur-Yvette
• C. J. Densham, R. J.S. Greenhalgh
  STFC/RAL, Chilton, Didcot, Oxon
• A. Enomoto, S. Kuroda, T. Okugi, T. Sanami, Y. Suetsugu, T. Tauchi
  KEK, Ibaraki
• A. Ferrari
  UU/ISV, Uppsala
• J. Gronberg
  LLNL, Livermore, California
• Y. Iwashita
  Kyoto ICR, Uji, Kyoto
• W. Lohmann
  DESY Zeuthen, Zeuthen
• L. Ma
  STFC/DL, Daresbury, Warrington, Cheshire
• T. M. Mattison
  UBC, Vancouver, B. C.
• T. S. Sanuki
  University of Tokyo, Tokyo
• V. I. Telnov
  BINP SB RAS, Novosibirsk
• E. T. Torrence
  University of Oregon, Eugene, Oregon
• D. Warner
  Colorado University at Boulder, Boulder, Colorado
• N. K. Watson
  Birmingham University, Birmingham
• H. Y. Yamamoto
  Tohoku University, Sendai

• T. W. Koeth
  
• L. Bellantoni, D. A. Edwards, H. Edwards, R. P. Fliller
  Fermilab, Batavia, Illinois

An experiment is being constructed at Fermilab's A0 Photoinjector to exchange longitudinal and transverse beam emittances. The exchange is preformed by an optics channel consisting of two dogleg bend sections with a transverse deflecting mode cavity between them. In this paper we discuss the construction of the TM110 Mode Cavity. The cavity, based on a superconducting design will be constructed of copper. In addition, the cavity will be cooled with liquid nitrogen to fit within power and mode spacing requirements. The TM110 cavity operating requirements are presented as will the detail of the design, construction, tuning, and commissioning of the TM110 cavity.