Centrality Dependence of the Balance Function in Pb–Pb Collisions (NA49)

1. Centrality Dependence of the Balance Function in Pb–Pb Collisions (NA49) P. CHRISTAKOGLOU – M. FARANTATOS A. PETRIDIS – M. VASSILIOU UNIVERSITY OF ATHENS P. E. Christakoglou HEP 2003

2. OUTLINE • Introduction – Balance Function definition • NA49 setup • Toy modelanalysis • Analysis of pp@158 GeV • Stability of results • Analysis of PbPb@158 AGeV • Stability of results • Centrality dependence • Summary • Future Plans P. E. Christakoglou HEP 2003

3. MOTIVATION • Motivated by the idea that hadrons are locally produced in charge – anticharge pairs. • We can measure separation of balancing charges. • Early pairs separate due to longitudinal expansion. • Later pairs are correlated at small Δy. • Can signal delayed hadronization. P. E. Christakoglou HEP 2003

4. BALANCE FUNCTION DEFINITION The Balance function is defined as a correlation in y of oppositely charged particles, minus the correlation of same charged particles, normalized to the total number of particles. where P2: relative rapidity P1: anywhere in the detector Normalization: Statistical Errors: Error in Balance Function: • Ref: • Bass-Danielewicz-Pratt, Phys. – Rev.Lett.85, 2000 • D. Drijard et al, Nucl. Phys. B(155), 1979 P. E. Christakoglou HEP 2003

5. Balance Functions (B.F) – How they work? : is the conditional probability of observing a particle of type b in bin p2 given the existence of a particle of type a in bin p1 Both terms are summed over all events , though pairs involve particles of the same event. P. E. Christakoglou HEP 2003

6. PROPERTIES OF B.F. ‘S WIDTH • The overall width of the Balance Function (B.F.) in relative rapidity is a combination of the thermal spread and the effect of diffusion. • Due to cooling the width falls with time (σtherm). • The effect of diffusion stretches the B.F. (σδn). • If the hadronization occurred at early times then the effect of collisions is to broaden the B.F. • On the other hand late stage hadronization suggests narrower B.F. P. E. Christakoglou HEP 2003

7. ANALYSIS STEPS • Toy model analysis • Analysis of pp@158 GeV data – 500K Events • Analysis of mixed pp@158 GeV data – 500k Events • Analysis of PbPb@158 AGeV data – 700K Events Centrality Dependence Study – 6 Centrality Bins • Analysis of mixed PbPb@158 AGeV data P. E. Christakoglou HEP 2003

8. TOY MODEL ANALYSIS During all steps of the toy model analysis we used Gaussian distributions as an input in order to simulate the pseudo – rapidity distributions according to NA49 data. • Multiplicity Dependence • Equal number of positive & negative • particles. • For each run this number is increased , • starting from 100 to 600 total particles • with a step of 100 (50 pos. & 50 neg.). • We analyze the whole interval of the • input distribution. P. E. Christakoglou HEP 2003

9. Net charge Dependence • Fixed number of total particles (400). • For each run the net charge is • increased , starting from 40 to 200. • The number of positive particles is • always bigger than that of the • negative particles. • We analyze the whole interval of the • distribution. • Correlation Dependence • Fixed number of total particles (400). • For each run , equal number of positive and • negative particles is doped symmetrically around • the mean of the input distribution. • The distributions of the correlated particles are • also Gaussians with a much narrower width. • For each run the number of the correlated • particles is increased , starting from 20 to 80. • We analyze in the interval mean ± 1.2 • (symmetrically around the mean ). P. E. Christakoglou HEP 2003

10. Correlation Width Dependence • Fixed number of total particles (400). • Fixed number of correlated particles (60). • The distributions of the correlated particles • are also Gaussians. • For each run the width of the distributions of • the correlated particles is increased. • We analyze in the interval mean ± 1.2 • (symmetrically around the mean ). • Constant Ratio • Multiplicity that is increased in each run. • Number of correlated particles is also • increased in each run. • The distributions of the correlated particles • are also Gaussians with a fixed width • (narrower than the initial input). • The ratio of correlated particles over • uncorrelated is constant. • We analyze in the interval mean ± 1.2 • (symmetrically around the mean ). P. E. Christakoglou HEP 2003

11. NA49 SETUP P. E. Christakoglou HEP 2003

12. NA49 PbPb@158 AGeV Event P. E. Christakoglou HEP 2003

13. pp @ 158 GeV SELECTION CRITERIA • Event Level Cuts:Those cuts are imposed in order to reduce a possible contamination from non target collisions. • Cuts on vertex coordinates x , y , z:, Δx = 1.0 cm | x0 = 0 cm, Δy = 1.0 cm | y0 = 0 cm, Δz = 3.0 cm | z0 = -580.0 cm • Number of tracks > 2 • At least one positive and one negative track per event. • Track Level Cuts:Those cuts are imposed in order to reduce the contamination of particles from secondary interactions , weak decays etc. • Cuts on the extrapolated distance of the closest approach (impact parameter) of the particle at the vertex plane and other quality cuts. P. E. Christakoglou HEP 2003

14. Balance function for pp@158 GeV real and mixed data P. E. Christakoglou HEP 2003

15. Comparison of the two previous balance functions P. E. Christakoglou HEP 2003

16. pp@158 GeV – Stability check P. E. Christakoglou HEP 2003

17. PbPb @ 158 AGeV SELECTION CRITERIA • Event Level Cuts:Those cuts are imposed in order to reduce a possible contamination from non target collisions. • Cuts on vertex coordinates x , y , z:, Δx = 1.0 cm | x0 = 0 cm, Δy = 1.0 cm | y0 = 0 cm, Δz = 3.0 cm | z0 = -578.9 cm • Number of tracks > 50 • At least one positive and one negative track per event. • Track Level Cuts:Those cuts are imposed in order to reduce the contamination of particles from secondary interactions , weak decays etc. • Cuts on the extrapolated distance of the closest approach (impact parameter) of the particle at the vertex plane and other quality cuts. P. E. Christakoglou HEP 2003

18. CENTRALITY DEFINITION • Ref: • Glenn Cooper Thesis P. E. Christakoglou HEP 2003

19. Balance functions for different centralities P. E. Christakoglou HEP 2003

20. PbPb@158 AGeV – Stability of B.F ‘s width P. E. Christakoglou HEP 2003

21. Balance functions for all veto bins – Mixed data P. E. Christakoglou HEP 2003

22. Centrality Dependence P. E. Christakoglou HEP 2003

23. STAR PRELIMINARY RESULTS P. E. Christakoglou HEP 2003

24. CONCLUSIONS We ‘ve developed a method (Balance Function) that could possibly signal delayed hadronization. • Toy model analysis : • B.F independent on multiplicity. • B.F independent on net charge. • B.F depends on the number of correlations. • B.F depends on the width of the distribution of the correlated particles. • Data analysis: • Analysis of pp@158 GeV real and mixed data (reference point). • Analysis of PbPb@158 AGeV real and mixed data – centrality dependence study: • B.F ‘s width decreases as we go from the most peripheral to the most central PbPb collisions. • The decrease is of the order of 12%. • STAR results show the same effect as NA49 data. • STAR ‘s decrease is of the order of 16%. The decrease of B.F. ‘s width could be due to: • Delayed hadronization compared with the characteristic 1 fm/c hadronization time. • Strong transverse flow. • Anomalously short diffusion of particles. • Decay of resonances that have lifetimes similar to the proposed time of hadronization. P. E. Christakoglou HEP 2003

25. OUTLOOK • Centrality dependence – Need for MC data for PbPb @ 158 AGeV in different centralities. • Study of Balance Function’s width dependence on the number of resonances that decay (M.C.). • Energy dependence – Analyze PbPb data for different energies . • System dependence – Study of Balance Function for different systems (CC – SiSi). P. E. Christakoglou HEP 2003

26. CERN – SPS • Acceleration of 208Pb nuclei in LINAC3 (LINear Accelerator). • Ions 208Pb53+ go through PSB (PS – Booster)  94 AMeV • Ions go through PS (Proton Synchrotron)  4.25 AGeV • Ions go through SPS (Super Proton Synchrotron)  e- are removed  158 AGeV • Every 20 sec  5 sec beam to deliver (~105 Pb ions/sec). • Target with 1% interaction length  end up with 103 events/sec . • Events with large nuclear overlap  10 events/sec (30 events/spill) • 4 weeks / year running period  5x106 events. P. E. Christakoglou HEP 2003

27. TPC – NA49 P. E. Christakoglou HEP 2003

28. GAS – RESOLUTIONS • VTPC : The gas mixture is NeCO2 (90:10) (high particle density) • MTPC : The gas mixture is ArCO2CH4 (90:5:5) (lower particle density) • Momentum resolution : P. E. Christakoglou HEP 2003

29. CALORIMETERS • Ring Calorimeter: To measure ET – 240 parts , 10 rings radially and 24 sectors azimuthally. • E – M:16 layers Pb – scintillators • Hadronic: 20 layers Fe – scintillators • Veto Calorimeter: To measure EL – Trigger on central events. • E – M: • Hadronic: P. E. Christakoglou HEP 2003

30. DETERMINATION OF EVENT CENTRALITY • Estimate of b by fraction of Cross Section A simple , model independent estimate of <b> in each centrality sample is made assuming <Eo> for an event sample increases monotonically with increasing b , so that: where dσ/dEo is the measured Eo spectrum and dσ/db is closely given by the geometrical cross – section 2πb since the probability of at least one nucleon – nucleon interaction is large. So b(Eo) is given by: P. E. Christakoglou HEP 2003

31. Estimate of Npart from spectra Within each centrality sample , an estimate of Npart can be obtained from the measurements of the and distributions along with model estimates of the yield of net neutrons and net hyperons . The distributions are used to estimate the total strangeness carried by mesons. By strangeness conservation , this total should be compensated by the net strangeness carried by . It is assumed that is equal to so that the net strangeness carried by mesons is twice . Since Ξ and Ω-carry more than one strange quark , the net strangeness carried by the hyperons is given by : Then in terms of measured quantities : P. E. Christakoglou HEP 2003