ALICE at LHC: getting ready for Physics

1. ALICE at LHC:getting ready for Physics Christian W. Fabjan, CERN for the ALICE Collaboration Quark Matter 2008, Jaipur 9.2.2008

2. Outline • Relativistic Ion Physics at LHC • Status of the Alice Experiment • Early days pp and ion physics • Physics Reach: a few challenging studies

3. LHC: Plasma Energy Density; Lifetime Energy density expected to increase by factor ~ 2 – 3 Lifetime of QGP by Factor ~ 2 – 3

4. LHC: extending the low-x Reach RHIC as opened the low-x frontier finding indications for new physics (CGC ?) LHC will lower the x- frontier by another factor 30 Can reach x = 3 * 10-6 in pp, 10-5 in PbPb

5. LHC: Cross-sections and Rates Cross-sections of interesting probes expected to increase by factors ~ 10 ( cc ) to ~ 102 ( bb ) to ~ > 105(very high pT jets)

6. The LHC Ion Collider √sNN (TeV) L0 (cm-2s-1) <L>/L0 (%) Run time (s/year) σgeom (b) Collision system pp 14.0 1031* 107 0.07 5.5 1027 70-50 106 * * 7.7 PbPb * Lmax (ALICE) = 1031 ** Lint (ALICE) ~ 0.7 nb-1/year Running conditions for ‘typical’ Alice year: + other collision systems: pA, lighter ions (Sn, Kr, Ar, O) energies (pp @ 5.5 TeV).

7. ALICE Collaboration > 1000 Members (63% from CERN MS) ~ 30 Countries ~ 100 Institutes India Alice : collaboration of Nuclear and Particle Physicists with strong engineering and industrial participation

8. ALICE: A Large Ion Collider Experiment at CERN-LHC Size: 16 x 26 meters Weight: 10,000 tonnes

9. Inner Tracking System ITS Status: installed; being commissioned • Three different Silicon detector technologies; two layers each • Pixels (SPD), Drift (SDD), Strips (SSD) • Δ(rφ) resolution: 12 (SPD), 38 (SDD), 20 (SSD) μm • Total material traversed at perpendicular incidence: 7 % X0 Posters by S. Moretto; G.J. Nooren

10. Inner Silicon Tracker Inner Tracking System ~ 10 m2 Si detectors, 6 layers Pixels, Drift, double sided Strips Pixels SPD Pixels Drift SDD Strips SSD

11. ITS Russian Dolls - Sliding the SSD/SDD over the SPD TPC SPD SSD/SDD J.P. Wessels - First Physics with ALICE

12. ALICE TPC • Optimized for dN/dη ≈ 8000 • l = 5 m, Ø = 5.6m, 88 m3, 570 k channels, • up to 80 Mbytes/event (after 0 suppression) • Features: • lightweight: 3% X0 total material for perpendicular tracks • Drift gas:Ne (86) / CO2 (9.5) / N2(4.5) + ~1ppm O2 • novel digital electronics (ALTRO) • highly integrated, digital shaping; tail cancellation;0-suppression; Baseline restoration • Powerful laser calibration system

13. RODS OROCs ENDPLATE IROCs ALICE TPC: 5 years construction

14. Commissioning the TPC electronics

15. Cosmics recorded in TPC@ALICE Commissioning with Cosmics and Laser tracks Spatial resolution and Electronics noise in experiment according to specifications σ(dE/dx) ≈ 5.5 to 6.5 %, depending on multiplicity (measurements and simulations) Status: installed; being commissioned

16. ‘Outer’ Central Detectors: TRD, TOF, HMPID, PHOS, EMCAL Transition Radiation Detector (TRD) • electron ID in central barrel p>1 GeV/c • fast trigger for high momentum particles (hadrons, electrons) • 540 detectors ~ 760m2 • 18 super modules • length: 7m • X/X0 ~ 22 % • 28 m3 Xe/CO2 (85/15) • 1.2 million channels Posters by R. Bailhache; K. Oyama Status: partially installed; being commissioned

17. TRD - Signal Generation & Processing

18. TRD Installation

19. Time of Flight: TOF • TOF: Timing, Triggering, PID • Δη = 1.70; Δφ = 2π; • 18 ‘Supermodules’ • Requirement: σ≈ 50 ps • Multi-gap Resistive Plate Chambers: MRPC’s • 10 gaps; 250 μm thick • Readout organized in 160 000 pads, 2.5*3.5 cm2 • Optimization possible, because we finally understand them… • A revolution in TOF PID Timing Resolution σ≈ 50 ps Poster by A. Alici

20. TOF: installation finished 04/08; being commissioned

21. High Momentum Particle Identifier: HMPID • Proximity Focused RICH • 11 m2 active detector area • 7 modules • - 0.6< η < 0.6; Δφ = 58 deg • CsI Photocathode read by 16100 pads • Threshold momentum = 1.21* (Particle Mass) • PID optimization for • 1 GeV < p < 6 GeV Poster by L. Monar

22. HMPID: Installed; being commissioned HMPID (Sept ’06)

23. PHOton Spectrometer: PHOS • PbO4W- crystal calorimeter for Photons, neutral mesons, 1 to > 100GeV • Crystals: 2.2*2.2 cm2 , 20 X0, APD R/O Operated at – 25 deg; 5 pe / MeV • σ(E) ≈ 3%; σ(x,y) ≈ 4 mm; σ(t) ≈ 1 ns; at 1GeV • - 0.12 < η < 0.12; Δφ = 100 deg; at R = 460 cm • L0 trigger available at < 900 ns • Module tested, calibrated in test beam; 1 or 2 modules to be installed in 04/08 • 3rd module during 2008; • Ultimately 5 modules with 18 000 crystals expected by 2010 Poster by Y. Kharlov

24. ElectroMagnetic Calorimeter: EMCAL Status: project approved in Dec 2007 2 of 12 supermodules early 2009 • Pb-Scintillator em calorimeter for • Jet physics in conjunction with tracking and PID • Approximately opposite to PHOS • -0.7 <η < 0.7; Δφ = 107 deg • EM resolution σ(E) < 0.1/√E • 13 000 projective towers in ‘Shashlik’ geometry with APD R/O • L0 trigger in < 900 ns for high-pT jets, photons, electrons

25. ALICE Tracking Performance TPC acceptance = 90% Momentum resolution ~ 5% @ 100 GeV Robust, redundant tracking from < 100 MeV/c to > 100 GeV/c Very little dependence on dN/dy up to dN/dy ≈ 8000 dNch/dy=6000 drop due to proton absorption Posters by P. Christiansen; R. Wan p/p < 5% at 100 GeV with careful control of systematics

26. Particle Identification in ALICE • ‘stable’ hadrons (π, K, p): 100 MeV/c < p < 5 GeV/c; (π and p with ~ 80 % purity to ~ 60 GeV/c) • dE/dx in silicon (ITS) and gas (TPC) + time-of-flight (TOF) + Cherenkov (RICH) • decay topologies (K0, K+, K-, Λ, D) • K and L decays beyond 10 GeV/c • leptons (e,μ ), photons, π0 • electrons TRD: p > 1 GeV/c, muons: p > 5 GeV/c, π0 in PHOS: 1 < p < 80 GeV/c • excellent particle ID up to ~ 50 to 60 GeV/c

27. Absorber Tracking chambers Conceptual Layout of Muon Spectrometer Trigger stations Dipole 8 Acceptance on single m: • p>4 GeV/c • - 4.0 < η< - 2.5 0 Trigger pt cut on single m: • Low (~1 GeV/c) • High (~2 Gev/c) ΔM/M ~ 1% at Υ- mass 5 10 15 8 20

28. Muon Spectrometer: Instrumentation Status: installed; being commissioned Talk by B. Espagnon • Tracking • 5 tracking stations with two planes each • Cathode pad chamber technology with 60 μm space resolution; • Electronics: preamp/shaper ASIC (‘MANAS’), designed and developed in India; total of 1.1* 106 channels • MANAS: first, large-scale production of a mixed-signal ASIC in India • Triggering • 2 Trigger stations with two planes each • RPC technology; operation in proportional or limited streamer mode • Dual threshold discriminator for optimum timing (σ< 2ns)

29. Steel cone from Finland Tungsten fromChina Building the ‘mundane’ Muon Absorber Graphite & Steel from India Lead from England Concrete from France, Engineering & Supervision by CERN Design by Russia (Sarov/ISTC) Italianpolyethylene

30. Partial view of Muon chambers

31. Muon Spectrometer: Indian Flavor The Indian team had the privilege to build the largest units of the Tracking chambers

32. ‘Forward Detectors’:FMD, T0, V0, ZDC, PMD FMD3 installed Posters by N. de Marco; T. Malkiewicz • FMD: Forward multiplicity detector • 3 planes of Si-pad detectors covering -3.4 < η < - 1.7; 1.7 < η < 5.0 • T0: 2 arrays of 12 quartz Cherenkov counters • Time reference for TOF; vertex measurement; 30 ps resolution • V0: 2 arrays of 32 scintillator tiles • trigger on centrality, luminosity monitor, beam-gas rejection; 0.6 ns resolution • ZDCs: 2 neutron and proton calorimeters at +- 116 m from IP; to measure spectators; 2 em calorimeters at -7m • Quartz fibre technology V0-A during assembly Proton ZDC

33. PMD: Photon Multiplicity Detector Poster by T. Nayak PMD modules after assembly at Kolkata Lead converter installed • Pre-shower detector for photon multiplicity • 6mm diameter hexagonal cells • Total of 220 000 channels covering 2.3 < η < 3.7 • Readout adopted from Muon tracking, using MANAS chip • All-Indian responsibility

34. Managing the Data: Trigger, HLT, DCS, DAQ, ECS • Central Trigger Processor (CTP) • Hierarchy of three Levels ( L0, L1, L2 ) • High-Level Trigger (HLT) : 1000 processors; scaleable to 20 000 • sharpened trigger decisions; data pre-processing and compression; • Detector Control System (DCS) • Data Acquisition (DAQ): Bandwidth 500MBytes/ s; planned: 1.2 GBytes/s (following Luminosity increase) • Experimental Control System (ECS) • top layer; interface to experiment operation • Raw Data rate / year : 2.5 PByte Status: all systems installed; operational, commissioning continuing Poster by O. Villalobos

35. Off-line Data processing 18TB Dec 2007: Data Processing during 1st global Commissioning Run systematic reconstruction of all RAW data Reconstructed events made available to collaboration Accumulated data • In 2007: • 65 Sites on 4 continents • 7500 CPUs • 1PB of storage Europe Africa Asia GRID operation during December Run NorthAmerica Talk by F. Carminati

36. Start-up Configuration: April 2008 • Complete - fully installed & commissioned • ITS, TPC, TOF, HMPID, MUONS, PMD, V0, T0, FMD, ZDC, ACORDE, TRIGGER, DAQ • Partially completed • TRD (20%) to be completed by 2009 • PHOS (40%) to be completed by 2010 • EMCAL (0%) to be completed by 2010/11 • At start-up full hadron and muon capabilities • Partial electron and photon capabilities

37. pp Physics with ALICE • ALICE has • momentum coverage from < 100 MeV/c to > 100 GeV/c • Excellent particle identification • At start-up • Possibly, short run at 900 GeV -> compare to known physics • At nominal energy: • ‘Alice’ luminosity ∫Ldt = 3·1030 cm-2 s-1 x 107 s = 30 pb-1 • N(min. bias) > 108 events ; few to 20 event-pile-up in TPC • Muon trigger at < 1 kHz • Electron trigger ~ few Hz • Needed reference data for heavy ion program • Multiplicity distributions • Measurement of strange, charm, beauty, quarkonia cross-sections • Baryon Transport Talk by K. Safarik Poster by R. Lietava

38. Charged Particle Acceptance • operating with fast multiplicity trigger L0 from Silicon Pixels • efficiency studied for- single diffractive- double diffractive- non-diffractiveevents Posters by J. Grosse-Oetringhaus, R. Lietava; T. Malkiewicz; R. Wan

39. p 0 K p s ´ yield p er – 5 0.1 0.01 10 0.4 0.4 – 4 2 10 e v ent statisti c s 4 4 4 4 4 104 10 10 10 10 10 n e e de d pp e v ents 5 6 8 9 4 4 10 10 10 10 10 10 n e e de d L*(1520) -> pK Initial Strange Particle Studies • based on Pythia for LHC • significant samples of strange particles in < 100 millionminimum bias events: • K0 : 7x106 • Λ : 106 • Ξ : 2x104 • Ω : 270 • detailed study of flavour composition Poster by O. Villalobos

40. Heavy Flavor Measurements • D0→ K + πfrom sec. vertices • B → e + X σ(vertex) = 50 μm at 1.5 GeV/c • sensitivity to range of pQCD predictions • (based on 109 events) Talk by M. Masera

41. Heavy Flavor in Muon Channel • J/ Ψ; Υ→μμ; - 4.0 < y < - 2.5 • Initial sample of 60000 J/y and 2000  sufficient to measure production cross-sections

42. Baryon Transport • Discriminate between two competing processes • Baryon number transport via quark exchange • Baryon number transport via ‘Baryon junction’ • With measurement of asymmetry A • Systematic errors: < 1% for p < .5 GeV/c • Experimental handles: • Study over large rapidity gap; • at LHC : Δη > 9 units • Study as function of multiplicity G.C. Rossi and G. Veneziano, Nucl. Phys B123 (1977) 507B.Z. Kopeliovich and B. Zakharov, Z. Phys. C43 (1989) 241  Poster by M. Oldenburg

43. ‘First Three Minutes’ Heavy Ion Physics • Fully commissioned Detector and Trigger • Reference data, alignment, calibration from pp run • 1/20 of nominal luminosity during one month • ∫Ldt = 5·1025 cm-2 s-1 x 106 s = 0.05 nb-1 for PbPb at 5.5 TeV • PbPbminbias = 107 events; PbPbcentral = 107 events • First 105 events: global event properties • multiplicity; η - density; elliptic flow • First 106 events: source characteristics • Particle spectra; resonances; differential flow; interferometry • First 107 events: Bulk Properties of medium • Jet quenching; Heavy Flavor production; Charmonia Talks by M. Masera, A. Morsch, S. Raniwala, K. Safarik Posters by N. de Marco; F. Noferini; N. van der Kolk; E. Scomparin

44. pt jet > (GeV/c) jets/event Pb+Pb accepted jets/month ^ 5 3.5 102 4.9 1010 q 50 7.7 10-2 1.5 107 100 3.5 10-3 8.1 105 150 4.8 10-4 1.2 105 200 1.1 10-4 2.8 104 Jet Production at LHC • Initial measurements up to 100 GeV (untriggered charged jets only) • Detailed study of fragmentation possible • Sensitive to energy loss mechanism • Accuracy on transport coefficient <> ~20% Talk by A. Morsch

45. Heavy Flavor quenching: D, B, RAA One year at nominal luminosity: 109 pp events;107 central PbPb events Probes colour charge dependence Probes mass dependence

46. Di-Muon mass spectrum • One Month (106sec) Pb-Pb collisions at nominal luminosity • Adequate statistics to study Υ- family and quench-scenarios J/Ψ ~ 3*105 Υ ~ 8000

47. Quarkonia production Υ ~ 8000 • J/Ψ ~ 3*105 • Suppression vs recombination study suppression scenarios

48. gall/gdec Thermal and hard photons from QGP Posters by R. Diaz Valdes; Y. Karlov; Y. Mao

49. gall/gdec gall/gdec Measuring Thermal Photons from the QGP ALICE sensitivity to thermal radiation without and with quenching of the away jet, measured relative to all Gammas (basically gammas from π0 ) Thermal photons above 3- 4 GeV expected to be measurable

50. Finally … • ALICE is becoming reality after almost 15 years in the making • 2nd Commissioning run to start next week, Feb11th for four weeks • Installation will be terminated in April • Further commissioning running until first beams, scheduled for summer 2008 • All systems on track for taking first pp collisions • ALICE is the general purpose Heavy Ion experiment, designed to address the very rich, expected physics program; • It is versatile enough to address the ‘Unknown’