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Harwood, L.

Paper Title Page
TPPP016 Beam Physics for the 12 GeV CEBAF Upgrade Project 1482
 
  • L. Merminga, J. F. Benesch, S.A. Bogacz, Y.-C. Chao, A. Freyberger, J.M. Grames, L. Harwood, R. Kazimi, G.A. Krafft, M. Spata, M. Tiefenback, M. Wiseman, B.C. Yunn, Y. Zhang
    Jefferson Lab, Newport News, Virginia
 
  Funding: Work supported by DOE Contract DE-AC05-84ER40150.

Beam physics aspects of the 12 GeV Upgrade of CEBAF are presented. The CEBAF Upgrade to 12 GeV is achieved via 5.5 recirculations through the linacs, and the installation of 10 new high-gradient cryomodules. A new experimental hall, Hall D, is envisioned at the end of North Linac. Simulation results for straight-through and recirculated injectors are summarized and compared. Beam transport designs are discussed and evaluated with respect to matching and beam breakup (BBU) optimization. Effects of synchrotron radiation excitation on the beam properties are calculated. BBU simulations and derived specifications for the damping of higher order modes of the new 7-cell cavities are presented. The energies that provide longitudinal polarization in multiple experimental halls simultaneously are calculated. Finally, a detailed optics design for the Hall D transport line has been obtained.

 
WOAD003 JLab 12-GeV Upgrade
 
  • A. Lung, L. Harwood
    Jefferson Lab, Newport News, Virginia
 
  Jefferson Lab is preparing to upgrade its 6 GeV Continuous Electron Beam Accelerator Facility (CEBAF) to 12 GeV reach in energy. The energy doubling will significantly extend the scientific reach in the three existing experimental Halls A, B and C, and the upgrade will add the capability of a newly constructed hall, Hall D, to study the ‘confinement of quarks’. The energy upgrade will be achieved by the addition of ten high performance high gradient SRF cryomodules into existing space in the north and south recirculating linacs that will enhance the energy per pass to the level of 2 GeV. The SRF modules will be constructed at JLab with achieved gradients in excess of 20 MV/m and associated power RF and controls. The cryogenics will be upgraded by 50%, the transport magnets enhanced to deal with the increased beam energy, and a special radiator placed in the path of the electron beam to produce up to 9 GeV photons for Hall D physics. The present status of the 12 GeV Upgrade project will be described along with a hint of the science to be achieved.