Gas Cherenkov detector for high momentum charged particle identification in the

1. 3rd INT. WORKSHOP ON HIGH-PT PHYSICS AT LHCMarch, 16-19, 2008 Tokay, Hungary Gas Cherenkov detector for high momentum charged particle identification in the ALICE experiment at LHC Giacomo Volpe Istituto Nazionale di Fisica Nucleare, Sezione di Bari, Italy.

2. ALICE experiment HMPID RICH , PID @ high pT TRD Electron ID, Tracking TOF PID @ intermediate pT TPC Main Tracking, PID with dE/dx ITS Vertexing, low pt tracking and PID with dE/dx MUON m-ID PHOS g,p0 -ID L3 Magnet B=0.2-0.5 T EMCal High energy g pioni ALICE is designed to study the physics of strongly interacting matter and the quark-gluon plasma (QGP) in nucleus-nucleus collisions (sNN = 5.5 TeV) at the LHC. The p-p physics will be study as well as reference data for the nucleus-nucleus analysis. + T0,V0, PMD,FMD and ZDC Forward rapidity region pioni

3. ALICE experiment p/K TPC + ITS (dE/dx) K/p e /p p/K TOF K/p p/K HMPID (RICH) K/p 0 1 2 3 4 5 p (GeV/c) TRDe /p 1 10 100 p (GeV/c) • ALICE has a unique capability, among the LHC experiments, of charged particle identification, due to the exploiting of different types of detectors: • ITS + TPC : low pT identification (up to p = 600 MeV/c). • TOF : covers intermediate pT region. • TRD : electrons identification. • HMPID : high pT region (1÷5 GeV/c). High-pT Physics at LHC, 17 March 2008 G. Volpe

4. ALICE PID upgrade RICH results: At RHIC has been observed a large enhancement of baryons and antibaryons relative to pions at intermediate pT≈ 2 - 5 GeV/c, while the neutral pions and inclusive charged hadrons are strongly suppressed at those pT. • The key issue is to understand what is the mechanism of the hadronization and the influence of this mechanism on the spectra of baryons and mesons. High-pT Physics at LHC, 17 March 2008 G. Volpe

5. ALICE PID upgrade • The baryon puzzle observed at RICH can be interpreted with the “partons recombination” or “coalescence” mechanism. • In the recombination scenario quark-antiquark pair close in the phase space can form a meson at hadronization, while three (anti)quark can form an (anti)baryon. At LHC where the density of jets is very high, a new phenomenon originates where the recombination of shower partons in neighboring jets can make a significant contribution. It is foreseen that the baryon enhancement will be present in a momentum range higher than at RHIC, pT = 10 ÷ 20 GeV/c. (ref. Rudolph C. Hwa, C. B. Yang, arXiv:nucl-th/0603053 v2, 21 Jun 2006)

6. ALICE PID upgrade Other authors using different arguments foresee also change in meson-baryon ratio for pT > 10 GeV/c. Jet quenching can leave signatures not only in the longitudinal and transverse jet energy and multiplicity distributions, but also in the hadrochemical composition of the jet fragments. S. Sapeta and U. A. Wiedemann, arXiv:0707.3494 [hep-ph], July 2007.

7. ALICE PID upgrade EMCal TPC g beam axis hadrons momentum ? • The use of the Electromagnetic Calorimeter opens interesting possibility to distinguish quark and gluon jets in gamma - jet events and subsequently the study of the probability of fragmentation in pions, kaons or protons. • Regardless of the theoretical interpretations it seems important to have the possibility to measure the meson-baryon ratio up to momenta well above the current limits of ALICE for a track-by-track identification. High-pT Physics at LHC, 17 March 2008 G. Volpe

8. VHMPID • ALICE-HMPID collaboration is studying the possibility to built a new detector to identify charged particles with momentum p > 10 GeV/c  VHMPID (Very High Momentum Particle Identification Detector). • Energy loss or Time of Flight measurements don’t allow to identify track-by-track in such momentum range. • Since the given space in the ALICE detector and the physics requirements it seems inevitable to use gas Cherenkov counters. • To use a gas Cherenkov detector in a magnetic field environment brings about the following key problems: thechoice of radiator gas, the photon detection and the detector geometry. • A combination of a gas with low value of refractive index, with the proven concept of large area CsI photocathodes, has been considered. • Depending on the particle momentum values, with VHMPID will be possible to have PID by means pattern recognition method or by threshold counters technique. • Simulation results will be presented. High-pT Physics at LHC, 17 March 2008 G. Volpe

9. Radiator gas • CF4(n ≈ 1.0005,gth ≈ 31.6)has the drawback to produce scintillation photons (Nph≈ 1200/MeV), that increase the background. • C4F10(n ≈ 1.0015, gth ≈ 18.9) • C5F12(n ≈ 1.002, gth ≈ 15.84)this gas has been used in the DELPHI RICH detector.

10. VHMPID • Photon detector • Pad-segmented CsI photocathode is combined with a MWPC with the same structure and characteristic of that used in the HMPID detector. • The gas used is CH4, the pads size is 0.8×0.84 cm2 (wire pitch 4.2 mm), and the average single electron pulse height is of 34 ADC channels (1 ADC = 0.17 fC ≈ 1000 e-) at 2050 V. • The chamber is separated from the radiator by a window (4 mm of thickness). High-pT Physics at LHC, 17 March 2008 G. Volpe

11. Photon detector An other option for the photon detector could be a GEM-like detector combined with a CsI photocathode (higher gain, photons feedback suppression). Principles of operation V. Peskov studies High-pT Physics at LHC, 17 March 2008 G. Volpe

12. VHMPID • The simulation has been executed using AliRoot, the official simulation framework of the ALICE experiment; • Different geometries has been taken into account; • C5F12 as radiator; • CaF2window. Material photon transmittances and CsI photocathode quantum efficiency High-pT Physics at LHC, 17 March 2008 G. Volpe

13. Studied setup Proximity-focusing like setup: Charged particles cross the radiator producing Cherenkov photons. On the chamber both charged particle and photon signals are present. Signal topology depends only on the track momentum. High-pT Physics at LHC, 17 March 2008 G. Volpe

14. Studied setup Focusing setup: the focusing properties of a spherical mirror of radius R = 240 cm, are exploited. The photons emitted in the radiator are focused in a plane that is located at R/2 from the mirror center, where the photon detector is placed. High-pT Physics at LHC, 17 March 2008 G. Volpe

15. Photon blob topology – proximity focusing setup Nph(b = 1) ≈ (1.4 eV-1cm-1)·(3 eV)·(180 cm) ≈ 760, but The number of photons detected is much less because of the absorption in the radiator gas and CsI quantum efficiency. 15 GeV/c <N> ≈ 43 <N> ≈ 91 3 GeV/c High-pT Physics at LHC, 17 March 2008 G. Volpe

16. Photon blob diamater • An algorithm to calculate the blob diameter has been implemented. • The pad with the largest values of the charge corresponds with the impact particle point. I consider R that contains the 98% of the total charged pads. The values in the figure refers to mean and RMS of a sample of 100 events. High-pT Physics at LHC, 17 March 2008 G. Volpe

17. Photon ring topology: focusing setup Nph(b = 1) ≈ (1.4 eV-1cm-1)·(3 eV)·(120 cm) ≈ 500 b≈ 1 High-pT Physics at LHC, 17 March 2008 G. Volpe

18. High-pT Physics at LHC, 17 March 2008 G. Volpe

19. High-pT Physics at LHC, 17 March 2008 G. Volpe

20. Track inclination angle = 10° Orthogonal track displaced 40 cm from the detector center. High-pT Physics at LHC, 17 March 2008 G. Volpe

21. Study of the detector response – proximity focusing like setup Parameters used Cherenkov photons Blob radius Blob pads number Photodetector Charged particle High-pT Physics at LHC, 17 March 2008 G. Volpe

22. Study of the detector responsebackground subtraction algorithm Charged particles Background produced by Pb-Pb collision event It considers pads with charge larger than 200 ADC channels It checks if that pad is a local maximum in pads charge values If the pad considered is a local maximum, it cuts that pad and the adjacent ones (the pads corresponding to the track to identify not are taken into account by this procedure) High-pT Physics at LHC, 17 March 2008 G. Volpe

23. High-pT Physics at LHC, 17 March 2008 G. Volpe

24. Pb-Pb collision events, considering the presence of MIPs background High-pT Physics at LHC, 17 March 2008 G. Volpe

25. Study of the detector response: focusing setup Radiator vessel Charged particle q Mirror 120 cm • In the case of focusing setup the determination of Cherenkov emission angle is possible. • Pattern recognition algorithm is needed to retrieve the emission angle. • A back-tracing algorithm has been implemented to retrieve the Cherenkov emission angle. It calculates the angle starting from the photon hit point coordinates, on the photon detector. Photodetector High-pT Physics at LHC, 17 March 2008 G. Volpe

26. Simulation results: Cherenkov angle b≈ 1 b≈ 1 High-pT Physics at LHC, 17 March 2008 G. Volpe

27. Simulation results: Cherenkov angle High-pT Physics at LHC, 17 March 2008 G. Volpe

28. Simulation results: Pb-Pb background HIJING generator dNch/dh = 4000 at mid rapidity High-pT Physics at LHC, 17 March 2008 G. Volpe

29. Background subtraction algorithm Hough transform method • The Hough Transform Method (HTM) is an efficient implementation of a generalized template matchingstrategy for detecting complex patterns in binary images. • In the case of the Cherenkov pattern recognition, the starting point of the analysis is a bidimensional map with the impact point (xp, yp) of the charged particles, hitting the detector plane with known incidence angles (θp, φp), and the coordinates (x, y) of hits due to both Cherenkov photons and background sources. • A “Hough counting space” is constructed for each charged particle, according to the following transform: • (x, y) → ((xp, yp, θp, φp) , hc) • (xp, yp, θp, φp) is provided by the tracking of the charged particle, so the transform will reduce the problem to a solution in a one-dimensional mapping space. • A hc bin with a certain width is defined. • The Cherenkov angle θcof the particle is provided by the average of the hcvaluesthat fall in the bin with the largest number of entries.

30. Simulation results: Cherenkov angle • Hough transform is used to discriminate the signal from the background. b≈ 1 High-pT Physics at LHC, 17 March 2008 G. Volpe

31. Simulation results: Cherenkov angle High-pT Physics at LHC, 17 March 2008 G. Volpe

32. Momentum C5F12 Particle Id. p < 2.5 GeV/c 0 ? K 2.5< p < 8 GeV/c 1 p p 0 K, p 2.5 < p < 8 GeV/c 8 < p < 14 GeV/c 1 p, K 0 p 8 < p < 14 GeV/c 15 < p < 26 GeV/c 1 p Momentum range for p, K and p identification in Pb-Pb collisions environment.

33. VHMPID in the ALICE apparatus PHOS VHMPID modules High-pT Physics at LHC, 17 March 2008 G. Volpe

34. Studied setup • The available space in the ALICE apparatus is not too much. The goal is to decrease much as possible the detector dimension. • C5F12 has a boiling point Tb= 28° C at 1 atm, implying a difficult use of it in ALICE setup, where the internal temperature could be more or less the same (heating plant is needed). • A setup with radiator length of 80 cm, C4F10 as radiator and SiO2 window has been also investigated. High-pT Physics at LHC, 17 March 2008 G. Volpe

35. Simulation results: Cherenkov angle b≈ 1 High-pT Physics at LHC, 17 March 2008 G. Volpe

36. Simulation results: Cherenkov angle High-pT Physics at LHC, 17 March 2008 G. Volpe

37. Momentum C4F10 Particle Id. p < 3 GeV/c 0 ? K 3< p < 9 GeV/c 1 p p 0 K, p 3 < p < 9 GeV/c 9 < p < 14 GeV/c 1 p, K 0 p 9 < p < 17 GeV/c 17 < p < 24 GeV/c 1 p Momentum range for p, K and p identification in Pb-Pb collisions environment.

38. Conclusions & Outlook • The focusing setup, since its smaller dimension, is the setup that the collaboration will develop. • The goal is to have a small detector performing good PID. The 80 cm setup will be better investigated. • To enrich the sample with interesting event, triggering option has been also considered, using a dedicated trigger (see L. Boldizsar talk) and/or photons in the EMCal. High-pT Physics at LHC, 17 March 2008 G. Volpe

39. Backup

40. Study of the detector response