Longitudinal beam loss mechanisms for LIU and LAGUNA beams

1. Longitudinal beam loss mechanisms for LIU and LAGUNA beams E. Shaposhnikova with input from T. Argyropoulos, T. Bohl, J. E. Muller, C. Lazaridis, H. Timko LIU-SPS collimation review CERN 21.11.2013

2. SPS Beam Performance *Feasibility including operational viability (especially in the PS) remains to be demonstrated LIU-SPS collimation review

3. LHC beam LIU-SPS collimation review

4. Distribution of losses in LHC cycle • Very large losses in the past, reduced with time (machine tuning, e-cloud scrubbing?) • Can be a serious limitation in future for very high intensity required by LIU for HL-LHC • Relative losses increase with intensity N, absolute ~ N2? • Losses occur • at capture (bunch shape) • on flat bottom (full bucket due to injected bunch shape) • during ramp above 120 GeV/c due to multi-bunch instabilities or/and controlled longitudinal emittance blow-up (1-2%) LIU-SPS collimation review

5. Capture loss due to PS bunch shape(after rotation in longitudinal phase space) Shape can be improved by higher PS voltage:=> tails are less populated but losses are there! operation: 5% loss H. Timko et al., ESME simulations of realistic bunch distribution from PS tomography (no intensity effects included) best results: 2.5% loss LIU-SPS collimation review

6. Capture losses: uncaptured beam after injection(200 MHz signal ) Injection at 26 GeV/c A few seconds later Uncaptured beam Uncapturedbeam is always moving to the left. Energy loss (dp/p < 0) due to resistive impedance? LIU-SPS collimation review

7. Transmission of 25 ns beamin MDs with Q20 optics (2012) J. Esteban Muller et al. => Large losses and also increase with intensity LIU-SPS collimation review

8. Losses Transmission (from BCT and Larger) ~ 85-89 % for single batch 90-92 % for 3 or 4 batches  continuous losses along flat bottom Single batch • larger inj. emittance • with similar intensities • scrapping on FB LIU-SPS collimation review T. Argyropoulos et al.

9. Voltage programs for Q20 (MDs) • 200 MHz voltage program settings: • 2.5 to 4.5 MV - 4 dips at injections • 4.5 MV constant • 3.5 to 4.5 MV – 1st injection and 2.5 to 4.5 MV – for the rest • As in III + 500 kV at acceleration and flat top (avoid losses for higher intensities) • As in IV but no first dip optimal • Voltage increase during ramp required for higher intensities • Voltage close to the limit • For higher intensities • particle losses • or • increase length of the cycle • longer LHC filling time T. Argyropoulos et al. LIU-SPS collimation review

10. Acceleration: voltage and power for nominal intensity in Q20 and Q26 Voltage Power => Power will beat the limit also during acceleration above nominal intensity! LIU-SPS collimation review

11. High intensity LHC beam • High intensity: Np = 1.36x1011 p/b at FT • TWC 200 MHz voltage program: case III Controlled emittance blow-up is difficult to optimise for high intensity beam LIU-SPS collimation review

12. High intensity FT (LBNO) beam LIU-SPS collimation review

13. Main intensity limitations in the SPSfor CNGS-type beam (LBNO) • Equipment heating (MKE, HOM couplers, beam instrumentation…) • Beam losses • Transverse damper (40 MHz bandwidth) • RF voltage and power, beam control: • Beam stability and bucket area for (un)controlled emittance blow-up • Maximum available voltage in the 200 MHz RF system: • 7.5 (8) MV • Maximum available RF power in one 200 MHz TW cavity: • 700 kW for full SPS ring (CNGS-type beam) LIU-SPS collimation review

14. LHC and CNGS-type beams in the SPS Nominal parameters of two main types of proton beam in the SPS • FT/CNGS beam from PS: • practically debunched beam • 5-turn extraction • no bunch-to-bucket transfer • injection below transition high intensity run LIU-SPS collimation review

15. Particle losses during cycle • Capture • Beam structure from the PS: de-bunched beam with 200 MHz density modulation => no bunch-to-bucket transfer • Ramp • Uncontrolled emittance blow-updue to instabilities during transition crossing and at higher energies (Nth ~ 1/E) • Limited RF bucket area due to beam loading with RF power limited to 750 kW LIU-SPS collimation review

16. Loss distribution during high intensity run (2004) • Injection losses - 5% • Losses on flat bottom ~ 2% • Particles in the kicker gap - losses at extraction ( 2%) => cleaning by trans. damper • Capture loss 3-4% • Beam losses at transition: 4% • Continuous losses after transition: 5% - 2% => early beam dump - main intensity limitation for the 2004 record of 5.3x1013 Critical losses LIU-SPS collimation review

17. Bunch length along the batch during cycle for high intensity beam (5.6x1013 injected, 15% losses)(AB-Note-2005-034 RF, T. Bohl et al.) t=1.315 s t=1.534 s γ>γt t=3.286 s t=4.163 s LIU-SPS collimation review

18. FT/CNGS acceleration cycle:voltage and power • at the moment maximum available voltage is used due to uncontrolled emittance blow–up during transition crossing - any voltage reduction leads to beam losses LIU-SPS collimation review

19. MD withCNGS Beam in 2012 • Goals of 2012 measurements : • Study beam stability • Verify present intensity limitations MD data analysis was done by C. Lazaridis Obtained profiles CNGS Cycle 200MHz RF Voltage Program 2 PS batches after 2nd injection in SPS Beam momentum ~3600 bunches LIU-SPS collimation review

20. Nominal CNGS Cycle • Injected beam is practically debunched • Bunches not well defined after injection • transition • instability at the end of the cycle Beam structure after injection a.u. Bunch Length Average and min-max for each frame Batch 1 Batch 2 LIU-SPS collimation review

21. RF Voltage optimizationat injection • RF voltage at injection was varied in range 0.6 - 2.0 MV leading to changes in emittance • Trying to reduce capture losses => Nominal 0.9 MV close to optimal MV Nominal voltage 1.99 MV 0.6 MV ms Average Bunch Length ns SPS BCT Batch 1 - 0.6 MV/1.99 V Greater bunch spread More capture losses Nominal voltage 0.6 MV Batch 2 - 0.6 MV/1.99 V s LIU-SPS collimation review

22. Transition crossing and after Relative Bunch Length Reference : 1450 ms Average Bunch Length Batch 1/Batch 2 Reference γtransition (1480 ms) Bunch number 1501 ms 1490 ms 1457 ms • Bunch oscillations start immediately after transition (1480.2 ms) LIU-SPS collimation review

23. End of cycle Relative Bunch Length Reference : 1546 ms Average Bunch Length Batch 1/Batch 2 Reference Bunch number 4278 ms 1932 ms 2760 ms 3588 ms • Beam is very unstable at the end of ramp • Small losses observed LIU-SPS collimation review

24. Reducing beam losses • Losses due to instabilities around 2.8 s in the cycle • Maximum 200 MHz RF voltage • Tried reducing voltage to improve stability • Constant bucket area • Increasing synchrotron frequency spread inside the bunch Nominal voltage Modified ms Beam Intensity For intensities ~3.7x1013 losses are 3.5% => 0.2% reduction in high-energy losses Proposed changes applied to CNGS cycle Bucket Area Nominal voltage Modified LIU-SPS collimation review

25. Possible future improvements for beam loss reduction • 200 MHz power upgrade – limit will be still at 750 KW (due to full ring), but with 2 extra sections • LLRF upgrade of 200 MHz RF • Separate capture of each PS batch in the SPS would allow voltage capture modulation (e.g. 0.9 MV increased to 2.5 MV) • Variable gain of 1-turn-delay feedback • Upgrade of the frequency range of the feed-forward system (below 26 GeV/c) • Use of the 800 MHz RF system during cycle • Impedance reduction • Q20 optics(?) LIU-SPS collimation review

26. The 200 MHz RF system Voltage available for acceleration with Pmax=0.7 MW 4200 bunches spaced by 5 ns N = 4.8x1013 (Irf = 0.73 A) -> V=7.5 MV N = 7x1013 (Irf = 1.06 A) -> V = 9 MV • Presently both voltage and power are at the limit: 7.5 MV used after transition crossing (due to uncontrolled longitudinal emittance blow-up) • Improvement after power upgrade with 6 cavities (18 sections) LIU-SPS collimation review

27. Voltage during FT/CNGS cycle for two optics Q26 Q20 limit => after transition crossing some bunches have emittance > 0.6 eVs => voltage above present limit of 7.5 MV even for 0.4 eVs LIU-SPS collimation review

28. Can new optics help to reduce uncontrolled emittance blow-up? Voltage program for 0.6 eVs Slip factor (~ beam stability) LIU-SPS collimation review

29. Summary • LHC beam • Capture losses are determined by S-shape of injected bunches • Better stability for larger PS emittance, but more losses as well • Flat bottom losses are defined by full bucket • High energy losses come from beam instabilities and controlled emittance blow-up in conjunction with limited RF voltage (power) • FT high intensity beam • Absence of bunch-to-bucket transfer will be always a source of capture loss • Beam control during transition crossing is difficult - a source of losses • Only small increase in available voltage can be expected after the 200 MHz power upgrade -> limited voltage (bucket) at high energies • Relative losses increase with intensity -> high absolute losses can be expected during HL-LHC era (and LBNO) in the SPS at high energies unless beam instabilities are eliminated at source (impedance) LIU-SPS collimation review

30. LIU-SPS upgrades • Main difference between the two beams: • injection at 14 GeV/c and transition crossing => different beam control (LLRF) • CNGS beam fills whole SPS ring and LHC beam – only half => different requirements for beam power (continuous and pulsed regimes) • bunch spacing => multi-bunch effects (instabilities, heating) • CNGS-type beam will profit from planned SPS upgrades: • impedance reduction (shielding of MKE kickers, …) • e-cloud mitigation • 200 MHz and 800 MHz RF upgrade • beam instrumentation • low γt (transition energy) optics? LIU-SPS collimation review