Critical beam losses during Commissioning & Initial Operation

1. Critical beam losses during Commissioning & Initial Operation Guillaume Robert-Demolaize (CERN and Univ. Joseph Fourier, Grenoble) with R. Assmann, S. Redaelli, C. Bracco & T. Weiler; thanks to B. Dehning, B, Holzer & L. Ponce

2. OUTLINE • Introduction • Loss distribution from betatron cleaning • Minimum workable BLM system for collimation studies • Conclusion – Future studies Critical Beam Losses during Commissioning and Initial Operation

3. Introduction • Purpose of the LHC Collimation system: provide cleaning efficiency and protection, using collimators and absorbers => ~ 40 elements per ring are being implemented in the machine (Phase 1 of the system) • About 3700 Beam Loss Monitors (BLMs) can be counted around the two rings of the machine => do we need all BLM information to understand the cleaning performance and losses from the “leaking halo” ? Critical Beam Losses during Commissioning and Initial Operation

4. Base principles of the LHC collimation system • Collimators intercept beam halos (first, secondary, …) with some leakage which gets lost around the ring: the cleaning inefficiency of the system is then defined as: • The leakage lost over a given length of the machine (10 cm in our studies) is then counted as local cleaning inefficiency (unit = m-1). • Goal of this presentation is to show that it is sufficient to useonly a limited number of BLMs for commissioning the collimation system. Critical Beam Losses during Commissioning and Initial Operation

5. Critical BLMs for collimation • There are two types of critical BLMs for the collimation system: -- BLMs at the collimators: needed from early on for the set-up of the collimators (experiments in SPS performed successfully in Fall 2004 for the first time),-- BLMs at loss locations of “leakage halo”: the halo exiting IR3/IR7 is lost in characteristic locations and not spread everywhere around the ring (implying all BLMs should be used)=> critical loss locations characterize the efficiency of our system: can we identify those critical locations (= BLMs) ?? Critical Beam Losses during Commissioning and Initial Operation

6. How to address this question • Performing full simulations with ALL movable LHC Collimation System equipments: 41 collimators/absorbers per ring for Phase 1. • Only betatron cleaning is considered in the following for on-momentum beam halo • Check leakage halo losses in cold elements of the machine • Notes: * results presented for Beam 1 only (Beam 2 tracking in preparation) * heavy computing effort in resources and time (CPU limited) * local energy deposition: FLUKA takes our data as input * losses at collimators: induced showers can propagate downstream Critical Beam Losses during Commissioning and Initial Operation

7. CPU usage ← granted by share with experiments ← limit of Collimation allocated CPUs 2 students - 2 fellows Tracking on 64+ CPUs Critical Beam Losses during Commissioning and Initial Operation

8. OUTLINE • Introduction • Loss distribution from betatron cleaning • Minimum workable BLM system for collimation studies • Conclusion – Future studies Critical Beam Losses during Commissioning and Initial Operation

9. Parameters for obtaining loss maps • Data done for the two types of tracked halo (horizontal and vertical) and the two optics defined as reference cases: -- injection optics: 450 GeV, b* = 17 m at all IPs, -- collision optics: 7 TeV, b* = 0.55 m at IP1 & IP5 (else 10 m). Intermediate b* values can be studied if necessary (in case of big losses in experimental insertions). • Assumed quench limit values: h =10-3 m-1 (injection) h =2 x 10-5 m-1 (collision) • Results presented in the following slides focus on the horizontal halo only. Critical Beam Losses during Commissioning and Initial Operation

10. Collimators settings – Injection (1/2) Critical Beam Losses during Commissioning and Initial Operation

11. Collimators settings – Injection (2/2) Critical Beam Losses during Commissioning and Initial Operation

12. Collimators settings – Top energy (1/2) Critical Beam Losses during Commissioning and Initial Operation

13. Collimators settings – Top energy (2/2) Critical Beam Losses during Commissioning and Initial Operation

14. Error scenarios In the following we consider free orbit oscillations, always at the worst phase (found in simulation scan), following 2 scenarios: • Static case: -- collimators are always re-centered around the perturbed orbit -- the error amplitude can reach the estimated aperture tolerances of 4 mm (injection optics) / 3 mm (collision optics) • Dynamic case: -- collimators are still centered on the nominal closed orbit -- peak amplitude of error is ~ 1.5 s Critical Beam Losses during Commissioning and Initial Operation

15. Loss map – 450 GeVIdeal case ▬► halo ↕x 5 => Ideal case: below the quench limit (factor 5); not true during start-up though Critical Beam Losses during Commissioning and Initial Operation

16. Sample perturbed orbit ▬► halo ↑ │ │ │ ± 4 mm │ │ ↓ Critical Beam Losses during Commissioning and Initial Operation

17. Loss map – 450 GeV Perturbed orbit – worst phase, 4 mm amplitude ▬► halo ↕x 2.5 => Loss of a factor 2 in efficiency at worst locations !!! Critical Beam Losses during Commissioning and Initial Operation

18. Going downstream from IR7 ▼ = critical BLM high dispersion ↓ high dispersion + high b ↓↓↓↓ ▼ ▼ ▼ ▼ ▼ ▼ Ideal case ▼ ▼ ▼ ▼ ▼ ▼ ▼ 4 mm orbit ▼ ▼ => Same loss locations !!! Modulation of the peaks: a way to measure orbit ??? Critical Beam Losses during Commissioning and Initial Operation

19. Effect of optic (dispersion) ↑ peak loss location => Losses due to first high dispersion location !!! Characteristic loss locations can be understood from halo properties and optics. Critical Beam Losses during Commissioning and Initial Operation

20. Why off-momentum losses for on-momentum primary halo ? • Collimators in IR7 intercept off-axis particles => induced proton-collimator material interaction follows several processes. • Single-diffracting scattering: generates off-momentum halo=> always lost at one of the first high dispersion points: critical locations for limiting losses are therefore well defined (as seen in the IR7 +Arc 7-8 case) • Sets fundamental limitation of the LHC betatron cleaning insertion: single-diffracting scattering can never be avoided !!! Critical Beam Losses during Commissioning and Initial Operation

21. IR8 + Arc 8-1 ▼ ▼ Ideal case ▼ ▼ 4 mm orbit Critical Beam Losses during Commissioning and Initial Operation

22. Effect of optic (beta) ← peak loss location => Losses due to high betatron location !!! Critical Beam Losses during Commissioning and Initial Operation

23. IR1 Ideal case 4 mm orbit Critical Beam Losses during Commissioning and Initial Operation

24. IR2 TDI.4L2 TCLIA.4R2 Losses here are due to scattering from TDI Ideal case 4 mm orbit Critical Beam Losses during Commissioning and Initial Operation

25. IR3 Remember: only betatron cleaning Ideal case ▼ ▼ 4 mm orbit Critical Beam Losses during Commissioning and Initial Operation

26. IR4 Ideal case 4 mm orbit Critical Beam Losses during Commissioning and Initial Operation

27. IR5 Ideal case 4 mm orbit Critical Beam Losses during Commissioning and Initial Operation

28. IR6 Losses at the TCDQ equipment: → problem of local showers downstream of it under study ▼ Ideal case 4 mm orbit ▼ => We made one turn after IR7: 13 critical BLMs identified at injection (in addition to the ones foreseen at the locations of collimators). Critical Beam Losses during Commissioning and Initial Operation

29. Going further in error amplitude │ │ ← specified orbit │ │ │ │ │ │ │ │ │ │ │ │ │ │ + 80 % + 130 % Critical Beam Losses during Commissioning and Initial Operation

30. 7 Tev Study halo ▬► IR2, IR5 & IR8: nominal crossing schemes IR1: where orbit perturbation is applied Static orbit: ± 4 mm in the arcs, ± 3 mm in the insertions (many thanks to W. Herr !!!) . Critical Beam Losses during Commissioning and Initial Operation

31. Going downstream from IR7 ↓high dispersion ▼ ▼ ▼ Ideal case ▼ high dispersion + high b ↓↓↓↓ ▼ ▼ ▼ ▼ ▼ ▼ ▼ ▼ With orbit error => From below quench limit to about twice above; additional BLMs show up, but most of them are at the same locations than injection case. Critical Beam Losses during Commissioning and Initial Operation

32. IR8 + Arc 8-1 ←TCTs: generate a new quartiary halo => critical BLMs to be located here as well Ideal case ▼ ▼ ▼ With orbit error ▼ ▼ ▼ Critical Beam Losses during Commissioning and Initial Operation

33. IR1 ← TCTs Ideal case With orbit error Critical Beam Losses during Commissioning and Initial Operation

34. IR2 ← TCTs Ideal case With orbit error Critical Beam Losses during Commissioning and Initial Operation

35. IR3 Remember: only betatron study so far Ideal case With orbit error Critical Beam Losses during Commissioning and Initial Operation

36. IR4 Ideal case With orbit error Critical Beam Losses during Commissioning and Initial Operation

37. IR5 Ideal case ← TCTs With orbit error Critical Beam Losses during Commissioning and Initial Operation

38. IR6 Losses at the TCDQ equipment: → problem of local showers downstream of it under study Ideal case With orbit error => After one complete turn: 18 critical locations (in addition to collimator ones and at the triplets) Critical Beam Losses during Commissioning and Initial Operation

39. Dynamic scenario - Process • Dynamic studies: collimators are not re-centered around the perturbed orbit. • Purpose of this scenario: check the sensitivity of the system to fast orbit changes => how does the system behave if a secondary collimator gets closer to become a primary (back to a single-stage system) ? What is the effect on the cleaning efficiency ? • In the following, only the collision optics case is presented (results for injection optics still being analyzed). Critical Beam Losses during Commissioning and Initial Operation

40. Effect on the cleaning system - Lattice TCP.C6L7 TCSG.B4L7 TCSG.6R7 ↓zero orbit change ↑critical secondary Critical Beam Losses during Commissioning and Initial Operation

41. Loss Map for a 0.95 s offset (only IR7 elements) same critical locations !!! ↓ => Loss of a factor 4 in local cleaning efficiency in IR7 !!! Critical Beam Losses during Commissioning and Initial Operation

42. OUTLINE • Introduction • Loss distribution from betatron cleaning • Minimum workable BLM system for collimation studies • Conclusion – Future studies Critical Beam Losses during Commissioning and Initial Operation

43. Requirements for commissioning • For commissioning of the LHC and its collimation system, one needs to be sure to operate in safe conditions => with the results presented here, we can already point out critical locations !! • The determined positions and peak values of losses can then be used to define a minimum workable LHC BLM system for collimation studies. Critical Beam Losses during Commissioning and Initial Operation

44. Summary table for injection black: nominal & perturbed case red: only in nominal case + collimator locations + critical locations for IR3 => 13 critical locations in total Critical Beam Losses during Commissioning and Initial Operation

45. Summary table for collision black: nominal & perturbed case red: only in nominal case blue: only in perturbed case + collimator locations + triplets + critical locations for IR3 => 18 critical locations in total, 6 of which being identical as in the injection case !! Critical Beam Losses during Commissioning and Initial Operation

46. Critical loss locations Critical Beam Losses during Commissioning and Initial Operation

47. Longitudinal distribution of beam losses – detailed studies for BLM positioning Dipole: all along the magnet Quadrupole: up to the middle of the magnet Critical Beam Losses during Commissioning and Initial Operation

48. Remarks • Early scenario checked (as seen in R. Assmann’s previous talk) as well: identical loss locations • Cases studies here refer to closed orbit perturbation spread all along the lattice: do not take into account possible local bumps in orbit!!!=> expect certainly some few additional high loss locations. • injection optics: many regions, not that critical collision optics: few regions, more critical Critical Beam Losses during Commissioning and Initial Operation

49. OUTLINE • Introduction • Loss distribution from betatron cleaning • Minimum workable BLM system for collimation studies • Conclusion – Future studies Critical Beam Losses during Commissioning and Initial Operation

50. Conclusion • The tools we developed allow us to study where the most critical regions of the machine are expected: -- for both mode of operation of the LHC (injection & collision), with still other optics possible, -- for any given scenario of beam losses, to check how flexible the system can be depending on the mode of operations. • In close collaboration with the BLM team, detection and monitoring of these critical regions shall be achieved to allow efficient commissioning of the LHC Collimation System. Critical Beam Losses during Commissioning and Initial Operation