Определение центральности столкновения ядер с использованием калориметра cпектаторов

1. Определение центральности столкновения ядер с использованием калориметра cпектаторов в эксперименте MPD@NICA M.Golubeva, F.Guber, A.Ivashkin, A.Kurepin, INR, Moscow A.Litvinenko, E.Litvinenko, A.Isupov, I.Migulina, V.Peresedov, JINR, Dubna A.Litvinenko,litvin@moonhe.jinr.ru A.Litvinenko VBLHEP JINR

2. Outline • Introduction • Some definitions • Spectators • UrQMD generator • LAQGSM generator • UrQMD - SHIELD - LAQGSM • Conclusions A.Litvinenko VBLHEP JINR

3. NICA A.Litvinenko VBLHEP JINR

4. MPD A.Litvinenko VBLHEP JINR

5. Nuclear-Nuclear collisions • Quasi-Classical picture • b – not observable • observablesb A.Litvinenko VBLHEP JINR

6. Centrality classification Geometrical cross section • Value of impact parameter • In percent from the geometrical cross section Corresponds to the region impact parameter Centrality

7. Centrality classification 1. Impact parameter 2.Fraction from total cross-section 3.Number of participant …. ?

8. Centrality classification

9. The importance of the centrality classification Elliptic flow Space eccentricity Nuclear Physics A V757, No. 1-2 , p.184,2005 elliptic flow scaling with space eccentricity short equlibration time A.Litvinenko VBLHEP JINR

10. The importance of the centrality study Nuclear modification factor Nuclear Physics A V757, No. 1-2 , p.184,2005 Jet Quenching – nuclear modification factor vs centrality A.Litvinenko VBLHEP JINR

11. The importance of the centrality study A.Litvinenko VBLHEP JINR

12. A.Litvinenko VBLHEP JINR

13. Nucleon spectators (spectrum) R.Ammarи et al., PismavJETF, V.94, No. 4, p.189, (1989) Yu.Bayukov et al., YaF V.35, No. 4, p.960, (1982) A.Litvinenko VBLHEP JINR

14. Spectator spectrum A.Litvinenko VBLHEP JINR

15. A.Litvinenko VBLHEP JINR

16. Front view of ZDC. The squares size is 5 x 5 cm x cm A.Litvinenko VBLHEP JINR

17. ZDC@MPD geometrical efficiency central hole out of ZDC A.Litvinenko VBLHEP JINR

18. Simulation Transport – Geant3 and Geant4, generates UrQMD and LAQGSM framework MpdRoot A.Litvinenko VBLHEP JINR

19. Optimistic results with UrQMD URQMD generator, Sqrt(S)=5 GeV Total kinetic energy of all nucleonsdirected to ZDC A.Litvinenko VBLHEP JINR

20. Optimistic results with UrQMD UrQMD generator, Sqrt(S)=9 GeV Total kinetic energy of all nucleonsdirected to ZDC A.Litvinenko VBLHEP JINR

21. The accuracy of impact parameter determination for MC with UrQMD A.Litvinenko VBLHEP JINR

22. The centrality resolution evaluations √S=9 AGeV

23. But The NA49 collaboration. Eur. Phys. J., A2, 383, (1998) A.Litvinenko VBLHEP JINR

24. But LAQGSM high-energy event generator A.Litvinenko VBLHEP JINR

25. Taking into account spectator fragments LAQGSM generator, Sqrt(S)=5 GeV Total kinetic energy of all nucleonsand fragments directed to ZDC A.Litvinenko VBLHEP JINR

26. Taking into account spectator fragments LAQGSM generator, Sqrt(S)=9 GeV Total kinetic energy of all nucleonsand fragments directed to ZDC A.Litvinenko VBLHEP JINR

27. SHIELD event generator A.Litvinenko VBLHEP JINR

28. LAQGSM, Sqrt(S)=5 GeV URQMD, Sqrt(S)=5 GeV Total kinetic energy of all nucleonsand fragments directed to ZDC A.Litvinenko VBLHEP JINR

29. A.Litvinenko VBLHEP JINR

30. Experimental data : the deposited energy for different types of spectators in dependence of the centrality The NA49 collaboration. Eur. Phys. J., A2, 383, (1998) At large impact parameters the most of spectatornucleons are bound in fragments. A.Litvinenko VBLHEP JINR

31. All nucleons directed to the hole of ZDC (rectangle 10x10cm2) 0 % - 60 % 60 % - 80 % 80 % - 100 % A.Litvinenko VBLHEP JINR

32. Experimental data : the deposited energy for different types of spectators in dependence of the centrality The NA49 collaboration. Eur. Phys. J., A2, 383, (1998) At large impact parameters the most of spectatornucleons are bound in fragments. A.Litvinenko VBLHEP JINR

33. The centrality resolution evaluations √S=9 AGeV Kinetic energy of all spectators directed to solid angle 5º 33

34. The centrality resolution evaluations √S=9 AGeV

35. The centrality resolution evaluations √S=9 AGeV

36. The centrality resolution evaluations √S=9 AGeV

37. The centrality determination: ZDC (energy) + number of charged barrel tracks A.Litvinenko VBLHEP JINR

38. UrQMD - SHIELD - LAQGSM b < 3 фм (0 – 4 %) A.Litvinenko VBLHEP JINR

39. UrQMD - SHIELD - LAQGSM 3 фм < b < 9.5 фм (4 – 40 %) A.Litvinenko VBLHEP JINR

40. UrQMD - SHIELD - LAQGSM 9.5 фм < b (40 – 100 %) A.Litvinenko VBLHEP JINR

41. Centrality determination in some experiment PHENIX NA49 STAR y=0 y=3 y>6 A.Litvinenko VBLHEP JINR

42. Conclusions • The SHIELD and LAQGSM could be used for NICA/MPD simulations under mpdroot. • The SHIELD and LAQGSM angular distributions of the spectators differ from URQMD picture. • The experimental study of the spectator distributions and calorimeter resolution have to be performed on the extracted beam of NUCLOTRON-M at the fixed target. A.Litvinenko VBLHEP JINR

43. Conclusions • Работа выполнена при поддержке грантов РФФИ 10-02-01036-а 11-02-01026-а A.Litvinenko VBLHEP JINR

44. Backup slides A.Litvinenko VBLHEP JINR

45. A.Litvinenko VBLHEP JINR

46. Fast evaluations: the movement of spectators at NICA/MPD • The conclusion: • Magnetic field ofMPD will not change the polar angles • for spectators atZDCposition • it will only slightly changes the azimutal angles A.Litvinenko VBLHEP JINR

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49. A.Litvinenko VBLHEP JINR

50. Centrality classification C.E.Aguilar et al., Brazilian Journal of Physics, V.34,No.1,p.319,(2004) A.Litvinenko VBLHEP JINR