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Status from the collimator impedance MD in the LHC

This article discusses the impedance of the LHC collimators and presents the results and conclusions from a recent MD (Machine Development) study. The study aims to assess the impact of collimator impedance on beam parameters and make recommendations for the Phase 2 collimation upgrade.

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Status from the collimator impedance MD in the LHC

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  1. Status from the collimator impedance MD in the LHC Collimation team: R. Assmann, R. Bruce, A. Rossi. Operation team: G.H. Hemelsoet, W. Venturini, V. Kain , G. Crockford. Impedance team (and friends): H. Burkhardt, W. Hofle, E. Métral, N. Mounet, B. Salvant. Many thanks for their help to: G. Arduini, M. Gasior, B. Goddard, S. Redaelli, F. Roncarolo, G. Rumolo, R. Steinhagen, D. Wollmann. LCU meeting – June 10th 2010

  2. This is a work in progress!!!

  3. Agenda • Context • Objectives • Methods • MD results • Conclusions and next steps

  4. Context:LHC impedance and collimators • LHC transverse impedance is predicted to be one of the potential limitations to reach nominal beam parameters for collisions at top energy (14 TeV/c). • LHC collimators are predicted to be the major contributors to the LHC transverse impedance at top energy. An upgrade of the collimation system is under study to reduce the impedance and improve the cleaning efficiency (Phase 2 collimation). • Impedance theories, EM simulations, RF bench measurements and MDs in the SPS with a prototype collimator were all consistent and showed that we seem to understand the impedance of a single collimator. • Now that beam is in the LHC, it is important to compare the LHC beam-based observations with predictions, in order to take decisions for the Phase 2.

  5. Context:previous LHC observations and predictions with different intensities • Several measurements performed at injection by Stefano Redaelli et al and Brennan Goddard et al. • They monitored the tunes for bunches of different intensities (see here): Qx~ -1.5 10-3and Qy~ -2 10-310/04/2010 (B2) Qx~ -5 10-4and Qy~ -2 10-316/04/2010 (B1) • Our predictions of tune shift with HeadTail macroparticle simulations for nominal collimator settings and nominal beam parameters at 450 GeV/c were Qx~ 3.5 10-4and Qy~ 4.4 10-4 for Nb~1.1011 p/b for Nb~1.1011 p/b  these measurements seem to indicate that the impedance may be a factor 5 higher than predicted by the model…  need for dedicated measurements, to try to record and control the beam parameters

  6. Agenda • Context • Objectives • Methods • MD results • Conclusions and next steps

  7. MD objectives 1) Assess the collimator impedance by (a) moving the jaws of a chosen set of LHC collimators (b) monitoring the transverse coherent tune shifts, and other beam parameters. 2) Assess the impedance of the whole LHC machine by (a) changing the beam intensity (through scraping) (b) monitoring the transverse coherent tune shifts, and other beam parameters. We got 4 hours of MD time (May 28th, 2010 - from 13:00 to 17:00).

  8. Agenda • Context • Objectives • Methods • MD results • Conclusions and next steps

  9. Methods • LHC impedance model is calculated through ZBASE • Includes theoretical models of phase 1 collimators at desired settings, beam screens, warm pipe, MQW, MBW and a BB impedance (from design report). • Significant contributors could be missing (kickers, PIMS, etc.). • Tune shift predictions with LHC model • Impedance  Sacherer formulae for single bunch transverse tune shifts • Wake  Headtail macroparticle simulations  SUSSIX  transverse tune shifts • MD • Record relevant beam parameters, in particular: intensity Nb, transverse tune shifts Q, bunch length L, as we expect

  10. Agenda • Summary • Context • Objectives • Methods • MD results • Moving IR 7 collimators from 5 sig to 15 sig • Moving injection protection collimators from nominal to retracted (TDIs+TCLIs) • Scraping in IR3 • Conclusions and next steps

  11. B2: Moving IR7 collimators

  12. Summary for beam 2 (moving IR7) Nb=9.3 1010 Bunchlength=1.4 ns Collimator gap open at 15 sigma Qy~-2.4 10-4 Qx<7 10-4 Collimator at 5 sig

  13. B2: effect on vertical tune shift of moving IR7 collimators 4*Std(sussix)=2.5 10-4 4*Std(fft)=2.9 10-4 out (15 ) out in (5 ) in  The tune shift is correlated to the collimator position.  Qy (meas.) ~ -2.4 10-4  Vertical tune shift prediction when moving IR7 from 15 to 5 (ZBASE model with measured collimator settings and Sacherer formula with measured beam settings): Qy (theory) ~ -2.0 10-4

  14. B2: effect on horizontal tune shift of moving IR7 collimators Tune peaks? Sideband -1 the H tune seems to jump from one peak to the next  difficult to estimate the tune shift, but we can write Qx<7e-4.

  15. IR7 in out in B2: effect on horizontal tune shift of moving IR7 collimators - Very large vertical tune signal… Coupling? - Many peaks around the tune make it difficult to analyze the horizontal tune. - During the MD, Wolfgang may have had a cleaner signal from the feedback pickups. To be checked.

  16. B2: Moving injection protection collimators

  17. B2: effect on horizontal tune shift of moving injection protection collimators (TDI+TCLIs) Tune shift due to injection protection collimators from B2 measurements: Qy~ -3 10-4 and Qx~0 Coarse extrapolation from nominal model (only TDI):Qy~ -1.2 10-4 and Qx~0 Qx~0 Qy~-3 10-4 TDI Collimator gap  Correlation between the collimator gap and the vertical tune shift  The horizontal tune switches to another peak when collimators are in. To be investigated in more detail.

  18. B2: Scraping the beam in IR3

  19. B2: effect of scraping in IR3 • Tune shift with intensity: • Scraping was performed with one collimator in IR3, resulting in a large bunch length decrease. • Accounting for this bunch length decrease and comparing with Sacherer tune shift from the nominal 450 GeV/c impedance model (collimators at nominal settings in the model instead of in the measurements): Qy Bunch length Intensity Qx From 9.3 1010 p to 1 1010 p, tune shifts are less than 10-3 and look similar in H and V

  20. B2: effect of scraping in IR3 Vertical tune shift (beam 2) Horizontal tune shift (beam 2) At Nb=9.3 1010 p/b, nominal model predicts Qy~-5.3 10-4 (5.9)andQx~-5.7 10-4 (6.3) measurements Qy~-7.3 10-4 andQx~-7.5 10-4 Warning!!! Preliminary results obtained with nominal collimator settings!!! The model is being refined now to account for exact collimator positions during the MD.

  21. B2: Overinjection

  22. Overinjection tune shift for beam 2 Overinjection tune shift is Qx~ -10-3 and Qy~ -1.5 10-3 (bunch length of 1.1 ns for high intensity, but not well defined for the pilot bunch)

  23. Conclusions and next steps • The predictions with the impedance model from ZBASE and the measurements on 28th May 2010 seem reasonably consistent. • More detailed simulations with Headtail should be performed. • We need to work on getting a cleaner tune measurement • The injection protection collimators may have a slightly larger impedance than expected, and this has to be investigated in more details. • The ZBASE impedance model should improved (e.g. adding new kickers and other suspected sources of impedance).

  24. Thank you for your attention!

  25. B1: Moving IR7 collimators

  26. B1: effect on tune shift of moving IR7 collimators Moving IR7 collimators from 5 sigma to 15 sigma leads to a tune increase of: 1 or 2 e-4 in horizontal plane (the tune jump to -1/+1 sideband shadows the graph... to be filtered) 3e-4 in vertical plane (first guess)

  27. B1: Moving injection protection collimators

  28. B1: Moving injection protection collimators Moving TDI collimators from 5 sigma to 15 sigma leads to a tune increase of: 2e-4 in vertical plane (first guess) ? in horizontal plane (the tune jump to +1 sideband shadows the graph... to be filtered)

  29. B1: scraping in IR3

  30. Scraping beam 1 from 0.91e11 p to 1e10p lead to a tune shift of 8e-4 in vertical plane horizontal plane is too jumpy to tell. Deeper analysis is needed. (Tune shift range between 3e-4 and 10 e-4)

  31. B1: overinjection

  32. Overinjection tune shift for beam 1 Overinjection tune shift is Qx~ -10-3 and Qy~ -1.3 10-3 (bunch length of 1.1 ns for high intensity, but not well defined for the pilot bunch)

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