45 th ICFA Beam Dynamic Workshop June 8–12, 2009, Cornell University, Ithaca New York Jim Crittenden Cornell Laboratory for Accelerator-Based Sciences.

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Presentation transcript:

45 th ICFA Beam Dynamic Workshop June 8–12, 2009, Cornell University, Ithaca New York Jim Crittenden Cornell Laboratory for Accelerator-Based Sciences and Education LCWS11 27 September 2011 Baseline Damping Ring Lattice Design Status

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 2 / 21 DTC02 Layout (D.L.Rubin) Circumference = m Harmonic number = m straights ~ 6 phase trombone cells Sixty 2.1-m long wigglers: 30-cm period, 14 poles B max = 2.16T Space for 16 RF cavities The cryostats for upper and lower positron rings are interleaved.

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 3 / 21 Cell length = 10.93m Bend length = 3.0m 75 cells/arc Arc Cell - FDBDF

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 4 / 21 Arc Wig-RF Straight Inj-Ext Straight Arc DTC02 Lattice Functions

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 5 / 21 RF Cells

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 6 / 21 Extraction Straight

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 7 / 21 Injection Straight

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 8 / 21 Circumference-Changing Chicane

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 9 / 21 Wiggler parameters 14 poles 30-cm period Wiggler length = 2.1m Cell length = 7.56 m 30 wiggler cells 2 wiggler cells Wiggler Cells

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 10 / 21 DTC02 Parameters

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 11 / 21 The lattice can accommodate 16 RF cavities If we assume 12 cavities then: Voltage/cavity in 10 Hz mode is 1.64 MV Power/coupler in 5 Hz, high power mode is 300 kW RF Cavities

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 12 / 21 Dynamic Aperture 5 Hz Periodic type wiggler model, includes vertical focusing and cubic nonlinearity

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 13 / 21 Periodic type wiggler model, includes vertical focusing and cubic nonlinearity Dynamic Aperture 10 Hz

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 14 / 21 Magnet Count (Damping Ring) ElementLength[m]StrengthNumber Arc Dipoles32.28 kG150 Circumference changing chicane dipoles kG28 Other dipoles2< 2.28 kG4 Arc Quadrupoles0.6< 0.6 m Quadrupoles in dispersion suppressor and straights 0.3< 0.55 m Sextupoles0.3< 4.34 m RF cavities3< 1.64 MV12 Wigglers T60 September 27, 2011 LCWS11 Global Design Effort14

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 15 / 21 Damping Wiggler Redesign Period reduced from 32 to 30 cm and number of poles increased from 12 to 14. Gap reduced from 8.64 cm to 7.62 cm. Peak field increased from 2.0 to 2.16 T. Design Considerations and Modeling Results for ILC Damping Ring Wigglers Based on the CESR-c Superconducting Wiggler PAC 2007 M.A.Palmer, J.A.Crittenden and J.Urban CESR-c Damping Ring Studies in the Context of the ILC Damping Ring Wigglers PAC 2005 J.Urban and G.Dugan

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 16 / 21 Wiggler Field Analytic Form for Symplectic Tracking The field map has been posted on the ILC/CesrTA wiki. A conceptual design for costing purposes is in preparation term optimization underway. Residuals presently at the level of a few gauss. The parameters have been posted on the wiki. A Magnetic Field Model for Wigglers and Undulators,, PAC 2003, D. Sagan, J.A. Crittenden, D.L. Rubin and E. Forest

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 17 / 21 Work at Cornell directed towards: – Implementation of mitigation recommendations into the vacuum chambers – Need chamber profiles for next round of physics simulations – Need chamber and system conceptual design for costing Vacuum System Design Effort

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 18 / 21 Clearing Electrode NEG strip s E-beam weld locations Copper Chamber Wiggler Chamber Concept I

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 19 / 21 We are considering a scenario where 2 wigglers with a quad in center are assembled as a unit and then installed. This would reduce the number of electrode chambers required. Wiggler Chamber Concept II

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 20 / 21 Radial outside of ring Aluminum Dipole Chamber Concept Radial inside of ring Locations of NEG strips

27 September 2011 LCWS11 Baseline Damping Ring Lattice Design Status / J.A.Crittenden 21 / 21 Tasks underway Concepts for drift, quadrupole, sextupole chambers in arcs Pumping requirements for straights Will in-situ bakeout of chambers in the straights be required? What are our options? Full ring wall profile for EC simulations Tasks to do Photon stop & masks conceptual design in wiggler region Full system concept for costing Vacuum System Summary

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