2.1 GHz Warm RF Cavity for LEReC Binping Xiao Collider-Accelerator Department, BNL June 15, 2015 LEReC Warm Cavity Review Meeting  June 15, 2015.

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Presentation transcript:

2.1 GHz Warm RF Cavity for LEReC Binping Xiao Collider-Accelerator Department, BNL June 15, 2015 LEReC Warm Cavity Review Meeting  June 15, 2015

Outline  Layout of the LEReC linac  Description of 2.1 GHz warm RF system  Summary 2

LEReC layout 3

4 Two 3-cell 2.1GHz cavities

Parameters 5 Phase IPhase II Frequency GHz Beam pipe ID [inch] 1.37 # of cells3 Voltage [kV] R/Q [Ohm]480 G [Ohm]170 Q Pcav [kW] RF power [kW] 1012 or 15?

2.1 GHz warm cavity: cell design 6 The 2.1 GHz bare cell: (a) perspective view; (b) front view; (c) side view. (a) (b) (c) Cavity end cell (a) perspective view (b) front view (c) side view.

2.1 GHz warm cavity: coupler design 7 Center cell with the FPC and tuner: (left) perspective view; (right) side view. WGHeight Pickup coupler (top) pickup coupler; (bottom) location of pickup coupler. To provide 10 8 Q ext, and 1W power at 200kV.

2.1 GHz warm cavity: 3cell 8 Parameters for 3-cell cavity (length unit in mm). Machining accuracy 0.001”. 50 degree coupling slot is chosen for the balance between coupling and shunt impedance for 3-cell. 4mm nose cone is chosen to maximize the shunt impedance. Radii of center cell and end cells are optimized for field flatness and resonance frequency at 0 tuner insertion. A gauge/arc detector port near RF window and a pickup port is designed (not shown here). A vacuum port near RF window is designed. JLab530 RF window (TiN coated) is placed far away from the cavity with an L-shaped waveguide to reduce the charge on the ceramic surface from beam.

2.1 GHz warm cavity: EM field 9 Magnetic field Electric field For 200 kV: Peak electric field 3.6 MV/m Peak magnetic field 14.3 mT

2.1 GHz warm cavity: tuner 10 Simulation results at different tuners’ penetrations: frequency, R/Q at β = 1, Q 0 after considering 1.3 factor, and the FPC’s external Q. RF performance for different tuner insertion Accelerating component of the electric field on beam axis for 3-cell cavity at 1Joule stored energy, with tuner penetrations to be -6, 0, 6, and 12 mm.

Summary 11  There will be two warm RF systems in LEReC: 704 MHz and 2.1 GHz cavities. For the 2.1 GHz warm RF system:  3-cell cylindrical cavity with nose cones and coupling slots is designed, and is optimized on shunt impedance.  FPC, vacuum port and gauge/arc detector port for FPC, tuner and Pickup coupler (Q ext 10 8 to provide ~1W power at 200kV) are designed.  A vacuum pump will be attached to the cavity using a Tee on one of the beam pipe.  Cavity is fine tuned for field flatness.  Cavity performance at different tuners’ penetrations is evaluated.  The 2.1 GHz RF design is finalized.

Thank you! 12