1. PHENIX @ RHIC R.K. CHOUDHURY BARC

2. Relativistic Heavy Ion Collider at Brookhaven National Laboratory (BNL), USA World’s First Heavy Ion Collider became operational in 2000 PHENIX, STAR, PHOBOS & BRAHMS

3. Relativistic Heavy Ion Collider @ BNL Facts about RHIC Tunnel: 3.66 m wide under the ground Circumference: 3.84 km Au Beam @200GeV/n speed: 99.995 % of c 1000’s of collisions per second 1000’s of particles produced per collision T ~ 10 12 K >> T (centre of the sun) 10 7 K Spin polarized proton beam upto 500GeV/n

4. PHENIX: Pioneering High Energy Nuclear Interaction eXperiment. PHENIX is designed specifically to measure direct probes of the collisions such as electrons, muons, phtons and hadrons.

5. 12 Countries, 58 Institutions, 480 participants: Country : Brazil, China, France, Germany, Hungary, India, Israel, Japan, Korea Russia, Sweden, USA International Aspect of PHENIX

6. PRIMARY MOTIVATION (Physics Driven) 1. Study of Quark Gluon Plasma (To create a mini universe in the laboratory what might have existed a few micro seconds after the big bang) 2. To understand the origin of Proton Spin

7. To map out the QCD phase diagram

9. What happens when two Au ions collide heads on ?

11. What happens inside a Detector ?

12. Off Line Analysis Begins Pattern Recognition

13. BARC CONTRIBUTION Fabrication of Muon Tracking Stations Simulation and Reconstruction Software

15. PHENIX RUN STATISTICS Run 01 2000 Au+Au @ 65 GeV/n for 5 weeks Run 02 2001 Au+Au @ 100 GeV/n for 16 weeks Run 03 2003 d+Au @ 100 GeV/n for 10 weeks Run 04 2004 Au+Au @ 100 GeV/n for 12 weeks Run 05 2005 Cu+Cu @ 100 GeV/n for 8 weeks Pol. p+p @ 100 GeV/n for 9 weeks Run 06 pol. p+p at 100 GeV/n for 14 weeks

16. Results from PHENIX (HI runs) -- Charged particle Multiplicities (stopping) -- Transverse Energy ( ~ 5 GeV/fm 3 ) -- Particle Yield Ratios, energy spectra (thermalisation) -- Elliptic Flow (v 2 scales with eccentricity: high collectivity) -- Two particle correlations -- Non-statistical Fluctuations -- Suppression of particle production at high p T -- Jet suppression -- Heavy flavour production (open charm,J/psi) -- Large (anti)baryon to pion ratio at intermediate p T

17. 1. Heavy flavour cross section: -->Calculable with QCD also include effects such as Shadowing -->Measure the cross section in pp, pPb and then extrapolate to Pb- Pb 2. Cold matter effects: --> Nuclear absorption and Comover scattering, e.g. J/psi + N --> D + D bar+ X 3. Energy loss in the medium: 4. Quarkonium suppression in QGP: When screening radius r D T D 5. Quarkonium Enhancement at LHC: No. of Q Qbar pairs produced at LHC is large. Possibility of recombination Heavy Flavour Physics

18. PHENIX - J/  Suppresion system size dependence CuCu  200 GeV/c AuAu  200 GeV/c dAu  200 GeV/c AuAu ee 200 GeV/c CuCu  62 GeV/c J/   muon arm 1.2 < |y| < 2.2 J/  ee Central arm -0.35 < y < 0.35 Factor ~3 suppression in central events CuCu ee 200 GeV/c

19. PHENIX - J/  Suppresion comparison to theory Models that were successful in describing SPS data fail to describe data at RHIC - too much suppression -

20. PHENIX - J/  Suppresion comparison to theory Implementing regeneration: much better agreement with the data

21. Suppressed high p T hadroproduction in Au+Au Au+Au   0 X (peripheral) Au+Au   0 X (central) Peripheral data agree well with Strong suppression in p+p (data & pQCD) plus N coll -scaling central Au+Au collisions

22. Suppressed high p T hadroproduction Discovery of high p T suppression (one of most significant results @ RHIC so far) N coll scaling (“hard” production) x5 suppression N part scaling (surface emission) R AA << 1: well below pQCD (collinear factorization) expectations for hard scattering cross-sections

23. Evidence in Favor of QGP Jet Tomography

24. Jet Quenching Data

25. A Strong Collective Behavior: FLOW

27. Definition of flow? Φ : azimuthal angle relative to reaction plane. f ( Φ ): azimuthal distribution of particles. Make Fourier expansion of f ( Φ ). 1 st Fourier coefficient v 1 = directed flow 2 nd Fourier coefficient v 2 = elliptic flow v n =, n = 1,2,… Central collision: v n =0, n = 1,2,… But one can have a radial flow. Elliptic Flow for only non-central collisions.

29. Elliptic Flow & Hydro. Calcs.

30. Has PHENIX found the Quark Gluon Plasma ? It is too early to say for sure, but the observation of jet suppression, indication of a very strong amount of flow etc. are very promising. The collected observations of all of the four RHIC experiments are consistent with a state of matter that has the properties of a perfect fluid comprised of quarks and gluons. fluid comprised of quarks and gluons.

31. Future Upgrades at RHIC RHIC Upgrade: Electron beam cooling x10 Luminosity, longer store time PHENIX Upgrade: Si Vertex Tracking Nose Cone Calorimeter High p T Aerogel Cerenkov Detector

32. Large Hadron Collider

33. CMS Detector

34. Si Preshower detector in Endcap ECAL

35. THANK YOU

36. 1. Heavy flavour cross section: -->Calculable with QCD also include effects such as Shadowing -->Measure the cross section in pp, pPb and then extrapolate to Pb- Pb 2. Cold matter effects: --> Nuclear absorption and Comover scattering, e.g. J/psi + N --> D + D bar+ X 3. Energy loss in the medium: 4. Quarkonium suppression in QGP: When screening radius r D T D 5. Quarkonium Enhancement at LHC: No. of Q Qbar pairs produced at LHC is large. Possibility of recombination Heavy Flavour Physics

37. PHENIX - J/  Suppresion system size dependence CuCu  200 GeV/c AuAu  200 GeV/c dAu  200 GeV/c AuAu ee 200 GeV/c CuCu  62 GeV/c J/   muon arm 1.2 < |y| < 2.2 J/  ee Central arm -0.35 < y < 0.35 Factor ~3 suppression in central events CuCu ee 200 GeV/c

38. PHENIX - J/  Suppresion comparison to theory Models that were successful in describing SPS data fail to describe data at RHIC - too much suppression -

39. PHENIX - J/  Suppresion comparison to theory Implementing regeneration: much better agreement with the data

40. Suppressed high p T hadroproduction in Au+Au Au+Au   0 X (peripheral) Au+Au   0 X (central) Peripheral data agree well with Strong suppression in p+p (data & pQCD) plus N coll -scaling central Au+Au collisions

41. Suppressed high p T hadroproduction Discovery of high p T suppression (one of most significant results @ RHIC so far) N coll scaling (“hard” production) x5 suppression N part scaling (surface emission) R AA << 1: well below pQCD (collinear factorization) expectations for hard scattering cross-sections

43. Definition of flow? Φ : azimuthal angle relative to reaction plane. f ( Φ ): azimuthal distribution of particles. Make Fourier expansion of f ( Φ ). 1 st Fourier coefficient v 1 = directed flow 2 nd Fourier coefficient v 2 = elliptic flow v n =, n = 1,2,… Central collision: v n =0, n = 1,2,… But one can have a radial flow. This talk: only non-central collisions.

45. Elliptic Flow & Hydro. Calcs.