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Direct photon detection in pp and PbPb collisions in the ALICE experiment at LHC

Direct photon detection in pp and PbPb collisions in the ALICE experiment at LHC. Yuri Kharlov For the ALICE PHOS collaboration 5 th International Conference on Perspectives in Hadronic Physics 22-26 May 2006. Outline. ALICE photon detectors Physics motivation Photon sources

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Direct photon detection in pp and PbPb collisions in the ALICE experiment at LHC

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  1. Direct photon detection in pp and PbPb collisions in the ALICE experiment at LHC Yuri Kharlov For the ALICE PHOS collaboration 5th International Conference on Perspectives in Hadronic Physics 22-26 May 2006

  2. Outline • ALICE photon detectors • Physics motivation • Photon sources • Expected rates • Experimental methods Direct photons in ALICE

  3. ALICE experiment at LHC ALICE is a dedicated heavy-ion experiment at LHC. Our aim is to study the physics of strongly interacting matter at extreme energy densities. 1000 scientists from 30 countries. ALICE Direct photons in ALICE

  4. ALICE setup On ALICE physics see a talk by M.Monteno on 24 May Direct photons in ALICE

  5. Photon detectors in ALICE EMCAL See a talk by N.Bianchi on 23 May PHOS Direct photons in ALICE

  6. PHOS crystals Base element: PbWO4 crystal grown at “North Crystals” enterprise in Russia RM=2.0 mm X0=8.9 mm =8.28 g/cm3 n=2.16 size: 222216 cm3 PHOS has 5 modules installed at 4.6 m apart from the ALICE interaction point. Each module contains 3584 crystals Total number of crystals: 17920 PHOS aperture: ||<0.13, =100 Energy range: E<100 GeV Direct photons in ALICE

  7. First PHOS module is assembled in April-May 2006 Direct photons in ALICE

  8. Main physics interests • Photon are highly penetrating particles which escape from the hot nuclear matter almost intact and, therefore, carry undistorted information from any stage of the nuclear matter evolution • Direct photons are produced in elementary interactions acts in the nuclear matter: • in hard QCD processes, observed mainly at high pT; • In emission of thermalized nuclear matter, observed mainly at low pT serve as a probe for thermal properties of the early phase of the nuclear reaction. Aka “thermal photons”. • Fragmentation photons • Decay photons reveal medium-induced modifications of hadron properties. • Interferometry of photons can be used as a tool to measure geometrical size of the source. See a talk by F.Arleo on 24 May Direct photons in ALICE

  9. Prompt g [O(aS)]: interaction of initial partons • Parton in-medium-modification imprinted in the final hadronic state • Prompt photons are not perturbed by the medium Medium-induced g [O(a2S)]:multiple scattering of final-state partons Photon sources (1) Direct photons in ALICE

  10. Thermal photons from QGP: Photons from HG: , , 0 Photon rates from QGP and HG might be similar, but can be distinguishable due to different space-time evolution Photon sources (2) Direct photons in ALICE

  11. Contributions to direct photon spectrum Direct photons in ALICE

  12. Photon predictions for p+p at LHC Start up scenario : 2 PHOS modules (Df=40, Dy=0.25) L=1030 cm-2s-1 T=10 days=8.6105 s LT= 8.6 108 mb-1 3·106 events/GeV at 1-2 GeV/c 15 events/GeV at 35 GeV/c 15 counts 35 Direct photons in ALICE

  13. p0 predictions for p+p at LHC Start up scenario : 2 PHOS modules (Df=40, Dy=0.25) L=1030 cm-2s-1 T=10 days=8.6105 s LT= 8.6 108 mb-1 3·108 events/GeV at 1-2 GeV/c 75 events/GeV at 50 GeV/c 75 counts 50 Direct photons in ALICE

  14. Decay g vs Direct g p+p collisions: • 0 dominates at all pT A+A collisions: • Jet quenching suppress 0 • RHIC: • Ng > Np for pT > 10 GeV/c • LHC: • Ng > Np for pT > 100 GeV/c Photon Yellow Report hep-ph/0311131 Direct photons in ALICE

  15. p0 nuclear modification factor • RAA for the 5% most central Pb+Pb collisions at sNN = 5.5A TeV with respect to p+p system. • Points obtained with NLO pQCD approximation Photon Yellow Report hep-ph/0311131 Direct photons in ALICE

  16. Photon predictions for Pb+Pb at LHC Start up scenario : 2 PHOS modules (Df=40, Dy=0.25) L=1026 cm-2s-1 T=10 days=8.6105 s LT= 8.6 104 mb-1 7·107 events/GeV at 1-2 GeV/c 50 events/GeV at 35 GeV/c 50 counts 35 Direct photons in ALICE

  17. p0 predictions for Pb+Pb at LHC Start up scenario : 2 PHOS modules (Df=40, Dy=0.25) L=1026 cm-2s-1 T=10 days=8.6105 s LT= 8.6 104 mb-1 2·109 events/GeV at 1-2 GeV/c 40 events/GeV at 50 GeV/c 40 counts 50 Direct photons in ALICE

  18. Particle identification in PHOS Photon are identified by 4 criteria: • Shape of the showers (e.m. or hadronic) • Charged particle matching by CPV detector • Time of flight measured by FEE • Photon isolation Direct photons in ALICE

  19. Photon efficiency and hadron contamination Single g Central Pb+Pb collisions Hadron contamination Single g + Pb-Pb Few % contamination Direct photons in ALICE

  20. Direct photons: experimental methods Direct photons spectrum at low pT can be measured statistically: • Raw spectrum of reconstructed and identified photons is accumulated • This raw spectrum is to be corrected for • hadron contamination • photon conversion • reconstruction and identification efficiencies • geometrical acceptance Direct photons in ALICE

  21. Experimental methods (cont’d) Decay photon spectrum is to be reconstructed: • 0 spectrum is reconstructed by 2-photon invariant mass distributions for each pT-bin • Combinatorial background is evaluated by event-mixing techniques • 0 spectrum is corrected for • reconstruction efficiency • photon conversion • geometrical acceptance • Similar procedures should be done for  and other neutral mesons if possible, heavy mesons contribution is evaluated by mT scaling • Reconstructed neutral meson spectra should be put into simulation to produce decay photon spectra Direct photons in ALICE

  22. 0 detection in pp via 2 inv.mass 1 GeV/c 2 GeV/c 3 GeV/c 4 GeV/c 5 GeV/c 6 GeV/c 7 GeV/c 8 GeV/c Practically no combinatorial background at pT>1 GeV/c Direct photons in ALICE

  23. 0 detection in Pb+Pb via 2 inv.mass 1 GeV/c 2 GeV/c 5 GeV/c 3 GeV/c 4 GeV/c 6 GeV/c 7 GeV/c 8 GeV/c 9 GeV/c 0 becomes visible over combinatorial background at pT>5 GeV/c Direct photons in ALICE

  24. p0 reconstruction in central Pb-Pb collisions: gg-mass spectrum Invariant mass spectrum of photon pairs has too high combinatorial background at low pT which obscures the p0 peak Example: gg-mass at pT=1 GeV/c in 200,000 central Pb-Pb collisions in PHOS Number of combinations: N(N-1)/2 S1: real gg-pairs p0 Direct photons in ALICE

  25. gg-mass spectrum in mixed events Combinatorial background can be constructed from totally uncorrelated photons from different events Example: gg-mass at pT=1 GeV/cof all combinations from 10 consequent events Number of combinations: 10N2 S2: gg-pairs in mixed events Direct photons in ALICE

  26. Combinatorial background normalization R=S1/S2: normalization Normalization of real-pair spectrum and mixing-event pair spectrum can be obtained in the mass region of uncorrelated pairs (200<Mgg<400 MeV/c2) Direct photons in ALICE

  27. Combinatorial background subtraction • After subtraction the p0 peak is revealed above almost zero background • But: • residual correlated pairs are observed at low Mgg which gives a background for photon interferometry studies (see later) • Statistical errors are higher due to subtraction of two large numbers S3=S1-R×S2 Direct photons in ALICE

  28. p0 detection in central Pb-Pb collisions 200,000 central Pb-Pb collisions (b<2 fm) 4 minutes of the LHC run at the nominal luminosity L=51026 cm-2s-1 Direct photons in ALICE

  29. 50 GeV 70 GeV l21 l21 90 GeV 110 GeV l21 l21 Direct photons at high pT Direct photons at high pT can be identified E-by-E by the shape of the shower g g p0 p0 g p0 g p0 Direct photons in ALICE

  30. Direct photons at high pT:efficiency and contamination pT = 90 GeV/c: P(g,g) = 60 % P(g,p0) = 5% Direct photons in ALICE

  31. Direct photons:sources of systematical errors • Errors in inclusive photon spectrum • Errors in decay photon spectrum • Errors in theoretical assumptions on background Direct photons in ALICE

  32. Expected direct photon excess over decay photons Direct photons in ALICE

  33. Photon interferometry С2 l 1/R 1 q Direct photons in ALICE

  34. C2 in Pb-Pb at 158 AGeV/c (WA98) Direct photons in ALICE

  35. Photon correlations:sources of systematical errors Systematic errors in photon HBT extration. • Apparatus effects: close cluster interference, cluster merging and splitting • Photon spectrum contamination and admixture of the hadron (electron)correlations • Background photon correlations due to • Residual correlation from Bose-Einstein correlated hadrons (00) • Resonance decays and conversion on material in front of PHOS • Residual correlations from collective flow, jets, etc. • Experimental resolution of the relative momentum Direct photons in ALICE

  36. Two-photon correlations:HIJING event Comparison of two-photon correlation function of primary photons and reconstructed one as well as decomposition of correlations due to decays of heavy resonances. Each contribution is shifted for clarity (all they go to zero at qinv > 30 MeV/c) KT= 200 MeV Both apparatus effects and background correlations are negligible at qinv>30 MeV/c Direct photons in ALICE

  37. Summary • ALICE PHOS can measure direct photons and 0 in pp and PbPb collisions with reasonable statistics during first 10 days up to pT=30-50 GeV/c. • PHOS is able to measure thermal photons with the uncertainties better than 10% • Main uncertainties come from photon identification efficiency and decay photon reconstruction. • PHOS can measure prompt photons at high pT with the uncertainties better then a few % • Main contamination is due to 0 misidentification • PHOS provides an opportunity to measure two-photon correlations, and in particular, direct photon HBT correlations • Background correlations and apparatus effects distort two-photon correlation function at q<20-30 MeV/c. Direct photons in ALICE

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