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MKP-I: Impedance considerations

MKP-I: Impedance considerations. C. Zannini , H. Bartosik , G. Rumolo , B. Salvant M. Barnes, T. Kramer, L. Sermeus. Overview. Simulation model Simulation results Proposed options Beam coupling impedance considerations Transverse impedance Longitudinal impedance Shielding

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MKP-I: Impedance considerations

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  1. MKP-I: Impedance considerations C. Zannini, H. Bartosik, G. Rumolo, B. Salvant M. Barnes, T. Kramer, L. Sermeus

  2. Overview • Simulation model • Simulation results • Proposed options • Beam coupling impedance considerations • Transverse impedance • Longitudinal impedance • Shielding • Beam induced power loss and transverse stability • Beam induced power loss • Transverse stability considerations • Beam coupling impedance with beam out

  3. 3D simulation model of the MKP-I

  4. Overview • Simulation model • Simulation results • Proposed options • Beam coupling impedance considerations • Transverse impedance • Longitudinal impedance • Shielding • Beam induced power loss and transverse stability • Beam induced power loss • Transverse stability considerations • Beam coupling impedance with beam out

  5. Proposed options sd xbeam

  6. Beam coupling impedance of the proposed options

  7. Beam coupling impedance of the proposed options

  8. Beam coupling impedance of the proposed options

  9. Beam coupling impedance of the proposed options Option 3 and Option4 result the more convenient solutions

  10. Overview • Simulation model • Simulation results • Proposed options • Beam coupling impedance considerations • Transverse impedance • Longitudinal impedance • Shielding • Beam induced power loss and transverse stability • Beam induced power loss • Transverse stability considerations • Beam coupling impedance with beam out

  11. SPS transverse impedance budget Vertical impedance: Comparison between present MKPs and MKP-I system The new MKP-I system has a slightly larger vertical impedance per meter length Smaller vertical aperture and shorter magnet length

  12. SPS transverse impedance budget Vertical impedance: Comparison between present MKPs and MKP-I system The new MKP-I system has a slightly larger vertical impedance per meter length Smaller vertical aperture and shorter magnet length

  13. SPS transverse impedance budget MKP-I system would significantly increase the vertical impedance of SPS kickers

  14. SPS transverse impedance budget MKP-I system would significantly increase the vertical impedance of SPS kickers

  15. SPS transverse impedance budget

  16. Overview • Simulation model • Simulation results • Proposed options • Beam coupling impedance considerations • Transverse impedance • Longitudinal impedance • Shielding • Beam induced power loss and transverse stability • Beam induced power loss • Transverse stability considerations • Beam coupling impedance with beam out

  17. SPS longitudinal impedance Comparison between present MKPs and MKP-I system The new MKP-I system has a slightly larger vertical impedance per meter length Smaller vertical aperture and shorter magnet length

  18. SPS longitudinal impedance Comparison between present MKPs and MKP-I system The new MKP-I system has a slightly larger vertical impedance per meter length Smaller vertical aperture and shorter magnet length

  19. SPS longitudinal impedance MKP-I system would significantly increase the longitudinal impedance of SPS kickers

  20. SPS longitudinal impedance Comparison between present SPS kickers and MKP-I system MKP-I system would significantly increase the longitudinal impedance of SPS kickers

  21. Overview • Simulation model • Simulation results • Proposed options • Beam coupling impedance considerations • Transverse impedance • Longitudinal impedance • Shielding • Beam induced power loss and transverse stability • Beam induced power loss • Transverse stability considerations • Beam coupling impedance with beam out

  22. Shielding: proposed options M. Barnes, T. Kramer, L. Sermeus G. Iadarola, G. Rumolo For electron cloud mitigation it is strongly recommended that the beam does not see the ceramic (see MKIs in LHC)

  23. Ceramic platewith titanium coating: preliminary simulations

  24. Ceramic platewith titanium coating: preliminary simulations

  25. Ceramic platewith titanium coating: preliminary simulations

  26. Ceramic platewith titanium coating: preliminary simulations

  27. Overview • Simulation model • Simulation results • Proposed options • Beam coupling impedance considerations • Transverse impedance • Longitudinal impedance • Shielding • Beam induced power loss and transverse stability • Beam induced power loss • Transverse stability considerations • Beam coupling impedance with beam out

  28. Beam induced power loss Beam induced heating The calculations for MKEs have been successfully benchmarked against beam induced heating observations during 2012

  29. Beam induced power loss Beam induced heating Present MKPs could strongly suffer of beam induced heating with high intensity beam

  30. Beam induced power loss Beam induced heating Present MKPs could strongly suffer of beam induced heating with high intensity beam Even worst for MKP-I

  31. Beam induced power loss Beam induced heating The shielding option (ceramic plate with titanium coating is not very efficient to reduce the beam induced power loss)

  32. Overview • Simulation model • Simulation results • Proposed options • Beam coupling impedance considerations • Transverse impedance • Longitudinal impedance • Shielding • Beam induced power loss and transverse stability • Beam induced power loss • Transverse stability considerations • Beam coupling impedance with beam out

  33. Transverse stability: Q20 MKP-I option3 wake model HEADTAIL simulation Transverse stability Present wake model reproduces the instability behavior (PhD thesis of H. Bartosik, to be published) HEADTAIL simulations from H. Bartosik The new MKP-I kicker system would reduce the transverse vertical instability threshold of ≈ 5%

  34. Overview • Simulation model • Simulation results • Proposed options • Beam coupling impedance considerations • Transverse impedance • Longitudinal impedance • Shielding • Beam induced power loss and transverse stability • Beam induced power loss • Transverse stability considerations • Beam coupling impedance with beam out

  35. Longitudinal impedance: beam out xout Having the circulating beam out of the magnet would dramatically reduce the impedance

  36. Transverse impedance: beam out xout Having the circulating beam out of the magnet would dramatically reduce the impedance

  37. Info from Benoit : very preliminary studies for the septum • Preliminary design provided by Bruno Balhan last week • Coarse approximations had to be made due to the complexity of the device, and lack of available information: • Laminations replaced by ferrites 4A4 • Longitudinal segmentation ignored • Magnetic laminations are partially shielded by steel holders • Several significant undamped longitudinal modes from 50 MHz onwards (i.e. fully in the beam spectrum) • Very large upstream and downstream aperture (frequencies above 500 MHz will escape in the beam pipe) • The impedance of this septum should be fully checked and it is likely that it should be optimized

  38. Summary and conclusions • The unshielded MKP-I would significantly contribute both to the longitudinal and transverse SPS beam coupling impedance. • A reduction of about 5% of the transverse instability threshold has been estimated. • The MKP-I with the present design could limit future operation with 25 ns beams due to the beam induced heating (similarly to the non-serigraphedMKE in 2012). • Circulating beam out would dramatically reduce both longitudinal and transverse impedance solving both heating and stability issues. • Preliminary simulations seems to indicate that the shielding option (ceramic plate with titanium coating) is not very efficient to reduce the beam induced heating.

  39. Thank you for your attention

  40. Appendix

  41. SPS transverse impedance budget Vertical impedance: Comparison between present MKPs and MKP-I system

  42. SPS transverse impedance budget Vertical impedance: Comparison between present MKPs and MKP-I system

  43. SPS longitudinal impedance Comparison between present MKPs and MKP-I system

  44. SPS longitudinal impedance Comparison between present MKPs and MKP-I system

  45. SPS longitudinal impedance: normalized impedance

  46. Effect of magnet length For a given cell length and total magnetic length in terms of beam coupling impedance a smaller number of magnets is more convenient

  47. Effect of magnet length For a given cell length and total magnetic length in terms of beam coupling impedance a smaller number of magnets is more convenient

  48. Effect of magnet length For a given cell length and total magnetic length in terms of beam coupling impedance a smaller number of magnets is more convenient

  49. Effect of magnet length For a given cell length and total magnetic length in terms of beam coupling impedance a smaller number of magnets is more convenient

  50. Effect of the beam position [mm] The broadband peak due to the ferrite decreases as the beam get closer to the inner conductor The peak due to the TEM mode increases as the beam get closer to the inner conductor

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