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Status of the sub-harmonic bunching system for the CLIC DB injector front end Hamed Shaker School of Particles and Accelerators, Institute for Research.

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Presentation on theme: "Status of the sub-harmonic bunching system for the CLIC DB injector front end Hamed Shaker School of Particles and Accelerators, Institute for Research."— Presentation transcript:

1 Status of the sub-harmonic bunching system for the CLIC DB injector front end Hamed Shaker School of Particles and Accelerators, Institute for Research in Fundamental Sciences, Iran ; CERN, Switzerland

2 Sub Harmonic Bunchers (SHBs) CLIC Collaboration Working meeting- 20122Hamed Shaker Phase coding 180  phase switch Acceleration 0 Deflection 0 / 2 Sub-harmonic bunching 0 / 2 odd buckets even buckets RF deflector 0 / 2 Gap creation and combination Main challenge of SHBs: Fast 180° phase flipping capability As talked with Thales for IOTs, 80 KW peak power and about 20 MHZ bandwidth (about 30 ns phase flipping) is achievable.

3 Phase flipping- how much fast? CLIC Collaboration Working meeting- 2012 Borrowed from Oleksiy Kononenko In the normal case the time interval between phase switching is constant (243.7 ns). In the Oleksiy model these intervals are not constant to have better energy dispersion at the end of main beam linac. It also give us an idea that how much the minimum phase flipping should be. The result shows us it should be less than 18ns. In my design I use 10ns similar to CTF3 SHBs. 3Hamed Shaker

4 Parameter for optimization Travelling Wave Structure For the known gap voltage and filling time our goal is to increase R/Q to reduce the input power. τ=10ns V=36.5 KV P d : Power disappears on surface. β : Coupling coefficient Q e = ωτ : External quality factor τ : Filling time R : Effective shunt impedance R’: Effective shunt impedance per length Q : Unloaded quality factor P: Source power V : Gap voltage W’ : Stored energy per length L: Structure length v g : Group velocity n : Cell numbers CLIC Collaboration Working meeting- 20124Hamed Shaker

5 Drive Beam Injector design in CDR Hamed ShakerCLIC Collaboration Working meeting- 20125 The values was found by S. Bettoni et al. during CLIC DB Injector design and optimization. Initial design of RF structures was started with these numbers. But these values should be corrected afterward depend on the structure and the power source restrictions. CLIC DB Injector (CDR) Field (MV/m) Length (cm) Voltage (KV) Input Power (CTF3 scaling) Gun140 (β=0.62) SHB - I0.22415.6351.1 MW SHB - II0.23415.636.51.2 MW SHB - III0.24915.638.81.4 MW To scale, using this fact that The CTF SHBs have the same length and their voltages are 20 KV with 40KW input power. The optimization process to find minimum power needed for an electrical coupling structure doesn’t shows a better result. Then we should looking for another structure.

6 Magnetic coupling TW structure l g rbrb rnrn θ1θ1 r1r1 t/2 rcrc lclc θcθc g40 mm rbrb 45 mm rnrn 4 mm θ1θ1 25° t (disk thickness)15 mm Frequency499.75 MHz l (for 108° phase advance per cell) ≈115.18 mm r1r1 161.55 mm rcrc 142 mm lclc 54 mm θcθc 86° Phase velocity0.64c CLIC Collaboration Working meeting- 20126Hamed Shaker

7 Four cells structure with waveguide couplers CLIC Collaboration Working meeting- 20127Hamed Shaker In this design for the first SHB about 73 MW peak power is needed for 10ns filling time and 36.5 KV gap voltage.

8 Phase flipping simulation – 10 ns CLIC Collaboration Working meeting- 20128Hamed Shaker Excitation signal – port 1 Output signal – port 2 Output signal – port 1 ≈ 14 ns ≈ 34 ns

9 Phase flipping simulation – 26 ns CLIC Collaboration Working meeting- 20129Hamed Shaker Excitation signal – port 1 Output signal – port 2 Output signal – port 1 ≈ 20 ns ≈ 40 ns

10 Phase flipping simulation with beam – 10 ns Hamed ShakerCLIC Collaboration Working meeting- 201210 port 1port 2 Beam Entrance Continues beam with 6A current Excitation signal from port 1 with 80 KW peak power.

11 Phase flipping simulation with beam – 10 ns Hamed ShakerCLIC Collaboration Working meeting- 201211 Excitation signal – port 1 Output signal – port 2 Output signal – port 1 ≈ 12 ns ≈ 44 ns

12 Phase flipping simulation with beam – 10 ns Hamed ShakerCLIC Collaboration Working meeting- 201212 About 5 bunches will be missed in comparison with about 120 bunches in each sub-pulse.

13 Conclusion One SHB design is ready for mechanical design. Looking for any RF power source (80 KW peak power, about 60 MHZ band width). Beam dynamic simulation of DB Injector should be start with new parameters. Another SHBs will be designed depend on the beam dynamic simulation result. Hamed ShakerCLIC Collaboration Working meeting- 201213

14 Acknowledgment Thanks Steffen Doebert, Roberto Corsini, Walter Wuencs, Alexej Grudiev, Jiaru Shi, Lars Thorndahl, Daniel Schulte and Oleksiy Kononenko for their helps. Hamed ShakerCLIC Collaboration Working meeting- 201214

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