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LHC performance in 2011

Dive into the operational intricacies of the Large Hadron Collider in 2011, exploring its design, challenges, and achievements, including the beam path, magnet systems, vacuum chambers, and energy targets.

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LHC performance in 2011

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  1. LHC performance in 2011 LHC performance in 2011 - LAL/Orsay J. Wenninger CERN Beams Department Operation group / LHC

  2. Outline Introduction Proton operation 2011 High intensity issues Outlook 2011 LHC performance in 2011 - LAL/Orsay

  3. The Large Hadron Collider LHC Installed in 26.7 km LEP tunnel Depth of 70-140 m Lake of Geneva LHC ring LHC performance in 2011 - LAL/Orsay CMS, Totem LHCb Control Room SPS ring ATLAS, LHCf ALICE

  4. - β* = 0.55 m (beam size =17 μm) - Crossing angle = 285 μrad - L = 1034 cm-2 s-1 LHC layout and parameters • 8 arcs (sectors), ~3 km each • 8 long straight sections (700 m each) • beams cross in 4 points • 2-in-1 magnet design with separate vacuum chambers → p-p collisions RF LHC performance in 2011 - LAL/Orsay

  5. LHC accelerator complex Beam 2 Beam 1 TI8 TI2 LHC proton path ≥ 7 seconds from source to LHC LHC performance in 2011 - LAL/Orsay The LHC needs most of the CERN accelerators...

  6. LHC dipole magnet • 1232 dipolemagnets. • B field 8.3 T (11.8 kA) @ 1.9 K (super-fluidHelium) • 2 magnets-in-one design : two beam tubes with an opening of 56 mm. • Operating challenges: • Dynamicfield changes at injection. • Verylowquenchlevels (~ mJ/cm3) LHC performance in 2011 - LAL/Orsay

  7. Vacuum chamber • The beams circulate in two ultra-high vacuum chambers, P ~10-10 mbar. • A Copper beam screen protects the bore of the magnet from heat deposition due to image currents, synchrotron light etc from the beam. • The beam screen is cooled to T = 4-20 K. Beam screen LHC performance in 2011 - LAL/Orsay Magnet bore Cooling channel (Helium)

  8. Tunnel View LHC performance in 2011 - LAL/Orsay

  9. LHC target energy: the way down When Why • All main magnets commissioned for 7TeV operation before installation • Detraining found when hardware commissioning sectors in 2008 • 5 TeV poses no problem • Difficult to exceed 6 TeV • Machine wide investigations following S34 incident showed problem with joints • Commissioning of new • Quench Protection System • (nQPS) 7 TeV 2002-2007 Design 12 kA 5 TeV Summer 2008 Detraining 9 kA LHC performance in 2011 - LAL/Orsay Late 2008 3.5 TeV Joints Spring 2009 6 kA 1.18 TeV Nov. 2009 nQPS 2 kA 450 GeV

  10. LHC target energy: the way up When What • Train magnets • 6.5 TeV is in reach • 7 TeV will take time • Repair joints • Complete pressure relief system • Commission nQPS system 7 TeV 2014/5 Training 6 TeV 2013 Stabilizers LHC performance in 2011 - LAL/Orsay 2011 3.5 TeV nQPS 2010 1.18 TeV 2009 450 GeV

  11. Luminosity : collider figure-of-merit The event rate N for a physics process with cross-section s is proprotional to the collider Luminosity L: Design k = number of bunches = 2808 N = no. protons per bunch = 1.15×1011 f = revolution frequency = 11.25 kHz s*x,s*y = beam sizes at collision point (hor./vert.) = 16 mm LHC performance in 2011 - LAL/Orsay • To maximize L: • Many bunches (k) • Many protons per bunch (N) • Small beam sizes s*x,y= (b*e)1/2 • b*: beam envelope (optics) • e: beam emittance, the phase space volume occupied by the beam (constant along the ring) High beam “brillance” N/e (particles per phase space volume)  Injector chain performance ! Small envelope  Strong focusing ! Optics property Beam property

  12. Stored energy • Increase with respect to existing accelerators : • A factor 2 in magnetic field • A factor 7 in beam energy • A factor 200 in stored beam energy LHC 2011 LHC performance in 2011 - LAL/Orsay Damage threshold

  13. To set the scale… A few cm long groove in a SPS vacuum chamber after the impact of ~1% of a nominal LHC beam (2 MJ) during an ‘incident’ LHC performance in 2011 - LAL/Orsay

  14. Collimation 1.2 m beam • To operate at nominal performance the LHC requires a large and complex collimation system • Previous colliders used collimators mostly for experimental background conditions - the LHC can only run with collimators. • Ensure ‘cohabitation’ of: • 100’s of MJ of stored beam energy, • super-conducting magnets with quench limits of few mJ/cm3 • Almost 100 collimators and absorbers. • Alignment tolerances <0.1 mm to ensure that over 99.99% of the protons are intercepted. • Primary and secondary collimators are made of Carbon to survive large beam loss. LHC performance in 2011 - LAL/Orsay

  15. Aperture and collimation • During experiments data taking, the aperture limit of the LHC is in the strong focusing quadrupoles (triplets) next to the experiments. • Hierarchy of collimators is essential to avoid quenching super-conducting magnets and for damage protection. • So far we never quenched a magnet with beam ! •  excellent machine and collimation system stability !!! Exp. LHC performance in 2011 - LAL/Orsay Triplet 18 σ Collimation hierarchy Tertiary 15 σ Tertiary 15 σ Dump Protection 10.5σ Secondary 8.8σ Primary 6σ

  16. Collimation • Collimator alignment is made with beam and then monitored from the loss distribution around ring. • Beam cleaning efficiencies ≥ 99.98% ~ as designed Beam loss monitor signal LHC performance in 2011 - LAL/Orsay TCT = tertiary coll. at the experiments.

  17. Beam dumping system • The dump is the only LHC element capable of absorbing the nominal beam. • Beam swept over dump surface (power load). Dump block • Ultra-high reliability and fail-safe system. Dilution kickers LHC performance in 2011 - LAL/Orsay Extraction septum magnets Extraction kickers 30 cm

  18. Outline Introduction Proton operation 2011 High intensity issues Outlook 2011 LHC performance in 2011 - LAL/Orsay

  19. The 2010 run • The 2010 run was the ‘learning to handle high intensity’ year. • Progressive intensity ramp up. • Initial operation with isolated bunches, moving to 150 ns spacingin September 2010. • Up to 368 bunches. • Test with 75 and 50 ns beams: •  Electron clouds. • Peak luminosity 2010: LHC performance in 2011 - LAL/Orsay 2×1032 cm-2s-1

  20. From 2010 to 2011 • Outcome the Evian (Dec 2010) and Chamonix (Jan 2011) Workshops: • No change of the beam energy: 3.5 TeV. • Reduction of b* better understanding of the machine aperture. • Faster ramp, faster squeeze. • 75 ns or 50 ns bunch spacing. LHC performance in 2011 - LAL/Orsay

  21. Bunch filling schemes • The LHC 400 MHz Radio-Frequency system provides 35’640 possible bunch positions every 2.5 ns (0.75 m) along the LHC circumference. • A priori any of those positions could be filled with a bunch… • The smallest bunch-to-bunch distance is fixed to 25 ns: max. number of bunches is 3564 (- some space for the dump kicker beam free region). • Because of the injector flexibility, the LHC can operate with isolated bunches or with trains of closely spaced bunches. • Startup 2010 : up to 50 isolated bunches (separation ≥ 1 ms). • Fall 2010 : 150 ns spacing - up to 368 bunches. • 2011 : start-up with 75 ns, now 50 ns. LHC performance in 2011 - LAL/Orsay = bunch position = filled position 2.5 ns … 25 ns 21

  22. 1092 bunches with 50 ns spacing 2 ns Beam 1 Beam abort gap LHC performance in 2011 - LAL/Orsay LHC circumference

  23. Ghost bunches • Ghost (parasitic) bunches are usually present between the main bunches (and essentially unavoidable), spaced by: • 2.5 ns : LHC RF system • 5 ns : SPS RF system • 25 ns : PS RF system • Amplitude ~ fraction of %. LHC performance in 2011 - LAL/Orsay ghost bunches 36 bunch train

  24. Experimental long straight sections LHC performance in 2011 - LAL/Orsay • The 2 LHC beams are brought together to collide in a ‘common’ region. • Over ~260 m, the beams circulate in the same vacuum chamber where they can potentially be ‘parasitic’ encounters (when the spacing is small enough).

  25. b* limits • The focusing at the IP is defined by b* which relates to the beam size s • b* is limited by the aperture of the triplet quadrupoles around the collision point and by the retraction margins between collimators. s2 = b* e • Smaller size s at the IP implies: •  Larger divergence (phase space conservation !) •  Faster beam size growth in the space from IP to first quadrupole ! LHC performance in 2011 - LAL/Orsay 33 mm e = 2.8 mm b* = 11 m 1.5 m Squeeze 90 mm

  26. Separation and crossing: example of ATLAS Horizontal plane: the beams are combined and then separated ATLAS IP 194 mm ~ 260 m LHC performance in 2011 - LAL/Orsay Common vacuum chamber Vertical plane: the beams are deflected to produce a crossing angle at the IP to avoid undesired encounters in the region of the common vac. chamber. ~ 7 mm a Not to scale ! 2011 !

  27. LHC Progress in 2010-11 at 3.5 TeV Low bunch intensity operation, first operational exp. with MPS Ramping up to 1 MJ, stability run at 1-2 MJ Reach out for the fb-1 ! LHC performance in 2011 - LAL/Orsay 2011 2010 Peak luminosity evolution

  28. Stored energy evolution • The stored energy in each beam has been pushed to 74 MJ. • Despite this large stored energy no magnet was ever quenched with circulating beam – well protected by the beam loss monitors ! • Quenches only occurred due to injection failures (with low intensity). 74 MJ LHC performance in 2011 - LAL/Orsay

  29. Luminosity 2011 Peak luminosity 1.26×1033 cm-2s-1 - 1092 bunches Integrated proton luminosity 2011 approaching 1 fb-1 LHCb luminosity limited to ~3×1032 cm-2s-1 by leveling (beams collide with transverse offsets) LHC performance in 2011 - LAL/Orsay 50 ns 75 ns

  30. Operational cycle • Cycle: • Injection • Ramp • Squeeze • Collide beams • Stable physics beams • Ramp down/cycle • Ramp and squeeze lengths were reduced in 2011 to < ½ hour. • Presently a good turn around is performed in 3 hours – best 2h 15. Beam charge(example for ions) Magnet current [A] LHC performance in 2011 - LAL/Orsay During the ‘squeeze’ phase, the betatron function at the collision points (b*) is reduced to increase the luminosity. Courtesy S. Redaelli

  31. Efficiency Intensity 1014 LHC performance in 2011 - LAL/Orsay 20-May Now Luminosity 1.2×1033 cm-2s-1 CMS/ATLAS LHCb

  32. Fill length • Luminosity lifetime is typically 25 hours (beam lifetimes > 100 hours). • Optimum fill length ~12-15 hours. • but beams are frequently dumped before due to HW issues. • Ideally we could produce up to ~ 50-60 pb-1/day ~ 350 pb-1/week LHC performance in 2011 - LAL/Orsay

  33. Efficiency • On average the LHC is colliding stable beams for physics ~8-10 hours per day (~30-35%). • Aim for improving the efficiency while increasing the luminosity further. • A significant fraction of the inefficiency is related to high intensity ! • Weekly production now around ~200 pb-1. LHC performance in 2011 - LAL/Orsay

  34. Outline Introduction Proton operation 2011 High intensity issues Outlook 2011 LHC performance in 2011 - LAL/Orsay

  35. High intensity issues • With 50 ns operation and with stored intensity of ~1014 protons (~1000 bunches) a number of issues related to high intensity have started to surface: • Vacuum pressure increases from electron clouds, • Radiation induced failures of critical tunnel electronics, • Heating of the beam screen temperature, • Heating of injection kickers, collimators, • Losses due to (supposed) dust particles, • RF beam loading, • Beam instabilities leading to emittance blow-up. • Those effects have slowed down the pace of the intensity increase. LHC performance in 2011 - LAL/Orsay

  36. Vacuum effects • Vacuum pressure increases were first observed around the 4 experiments at the moment the LHC switched to 150 ns train operation in 2010 – issue becomes more critical as the intensity increases and the bunch separation is reduced. • Effects can be suppressed by solenoids (CMS, ALICE stray fields…). • When the first 50 ns beams were injected into the LHC in 2010, the vacuum pressure increases were too large for operation. • Pressures easily exceeded 10-6 mbar (normal is 10-9 or less) leading to closure of the vacuum valves. • Signs of cleaning by beam, with strong dependence on bunch intensity and bunch spacing. • Consistent with the signature of electron clouds. LHC performance in 2011 - LAL/Orsay

  37. Electron clouds • … affect high intensity beams with positive charge and closely spaced bunches. • Electrons are generated at the vacuum chamber surface by beam impact, photons… • If the probability to emit secondary e- is high (enough), more e- are produced and accelerated by the field of a following bunch(es). Multiplication starts… • Electron energies are in the 10- few 100 eV range. • The cloud of e- can drive pressure rise, beam instabilities and possibly overload the cryogenic system by the heat deposited on the chamber walls ! •  The cloud can ‘cure itself’: the impact of the electrons cleans the surface (Carbon migration), reduces the electron emission probability and eventually the cloud disappears – ‘beam scrubbing’ LHC performance in 2011 - LAL/Orsay Bunch N+2 accelerates the e-, more multiplication… Bunch N+1 accelerates the e-, multiplication at impact Bunch N liberates an e- e- e- N+2 N+1 N ++++++ ++++++ ++++++ e-

  38. 75 and 50 ns Bunch Spacing • There is a strong dependence of electron clouds on bunch spacing. • For this reason operation in 2011 started with 75 ns beams. LHC performance in 2011 - LAL/Orsay Factor 2 between the slope for 50 ns than 75 ns >> importance of bunch spacing Courtesy J.M. Jimenez

  39. ‘Scrubbing’ to overcome e-clouds • Store as much beam as you can at injection (run at the limit of the vacuum / beam stability). • Must keep a high intensity and strong cloud activity since more cloud means more cloud cleaning… • Operate for some time, then re-inject fresh beam/higher intensity, always staying at the vacuum / stability limit. • Iterate until conditions are acceptable / good. • This takes some days... • In April 2011 a ~10 days ‘scrubbing’ run at 450 GeV allowed us to prepare the vacuum conditions for operation with 50 ns beams. • Up to 1080 bunches. • Bunch intensities up to 1.5×1011 p. LHC performance in 2011 - LAL/Orsay

  40. Vacuum cleaning with beam • Pressure decrease (normalized to intensity) as a function of effective beam time. • Gain one order of magnitude / 15 hours. LHC performance in 2011 - LAL/Orsay Courtesy J.M. Jimenez

  41. Blow up from e-clouds Example of bunch by bunch transverse sizes with 804 bunches / beam With strong electron cloud activity… LHC performance in 2011 - LAL/Orsay … and after some time of vac. chamber scrubbing ! LHC 8:30 meeting

  42. Radiation induced problems • With the increasing luminosity tunnel electronics starts to suffer from SEE (Single Event Errors). • In particular the quench protection ad cryogenics systems  frequent need for access to reset/repair. Collisions points Collimators LHC performance in 2011 - LAL/Orsay Loss rate S

  43. Mitigation of radiation effects • The mitigation of radiation effects is a long term program. • Relocation of equipment away from the tunnel, sometimes to the surface. • Improvement of embedded (FPGA) codes to cope with errors in non-critical parts and avoid reset involving tunnel access (quench protection). • Some ‘light’ work is done in the technical stops. • Radiation effect are expected to affect the LHC performance in the range of 1033 cm-2s-1 – the limit is clearly ‘soft’ : trade-off between peak luminosity and efficiency. LHC performance in 2011 - LAL/Orsay

  44. Beam screen temperatures Beam screen as seen by the beam Cold Bore (2K) • The beam screen (BS) shields the magnet cold bore from the beams. • Gases are trapped on the cold bore (colder than BS). • In the presence of beam, the beam screen maybe be heated by • vacuum pressure increase / electron clouds, • RF heating from EM fields. LHC performance in 2011 - LAL/Orsay • In some cases (triplets) out-gassing from the BS has been observed – very careful T control during technical (or cryo) stops. • Part of the effect could be correlated to (too) short bunches at 3.5. • Increased bunch length blow-up.

  45. IT beam-screen temperatures • Triplet BS temperature tricky to stabilise at injection and in the ramp. • Fine tuning/manual intervention by cryo operators. • Effect no fully understood. Injection /ramp 3.5 TeV stable beams dump LBOC, BS_Cryo facts BS T (K) 25 K 17 K Courtesy S. Claudet

  46. Surprise, surprise ! • Very fast beam loss events (~ millisecond) in super-conducting regions of the LHC have been THE surprise of 2010 – nicknamed UFOs (Unidentified Falling Object). • 18 beams dumps by UFO events in 2010, 10 dumps in 2011. • Beam loss thresholds were increased by factor 5 between 2010-11 (from experience – no quenches). • Most likely small (10’s mm) objects (dust…) ‘entering’ the beam. LHC performance in 2011 - LAL/Orsay • Some events correlated in time and space to roman pot movements. • Possibly re-expelled after charging up by ionization.

  47. Example of a UFO (152 bunches/2010) Beam loss monitor post-mortem LHCb IR7 IR1 Arc Arc LHC performance in 2011 - LAL/Orsay s Time evolution of loss 1 bin = 40 ms 0.5 ms Dump trigger (losses exceed threshold)

  48. UFO amplitudes • In 2011 ~5000 UFO events have been observed. • 10 events led to a beam dump. • Most of the events are weak and do not pose any problem. • Operation mostly suffers from the tail of events with losses exceeding the loss monitor thresholds (set for quench prevention). • An issue for 7 TeV / beam operation  lower quench thresholds. nominal arc threshold 7 TeV LHC performance in 2011 - LAL/Orsay Events 4905 candidate UFOs at 3.5 TeV. Loss ampl./ loss monitor threshold Courtesy T. Baer

  49. UFO rate in 2011 1510 candidate UFOs during stable beams. Signal RS05 > 2∙10-4Gy/s. LHC performance in 2011 - LAL/Orsay 228 b 36 bpi 480 b 72 bpi 768 b 72 bpi 768 b 72 bpi 912 b 108 bpi 1092 b 108 bpi 336 b 72 bpi 480 b 36 bpi 480 b 72 bpi 624 b 72 bpi 336 b 72 bpi 768 b 108 bpi 480 b 36 bpi UFO Rate ~ independent of no. bunches ~ 10 / hour

  50. UFO distribution in ring 450 GeV591 candidate UFOs. Signal RS05 > 5∙10-4Gy/s. 3.5 TeV1096 candidate UFOs. Signal RS05 > 5∙10-4Gy/s. LHC performance in 2011 - LAL/Orsay Mainly UFOs around injection kickers (MKI) The UFOs are distributed around the machine. About 7% of all UFOs are around the injection kickers. .

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