J/ ψ Production in p+p and d+Au Collisions at sqrt(S_NN) = 200 GeV at STAR

1. J/ψ Production in p+p and d+Au Collisions at sqrt(S_NN) = 200 GeV at STAR Chris Perkins UC Berkeley/Space Sciences Laboratory Stony Brook University For the STAR Collaboration 3/31/2009

2. Motivation – Mid-Rapidity |η| < 1 • Possible Heavy Quarkonia production mechanism at RHIC energy • Insight into heavy flavor transport through the medium • Suppression and color screening • 2 and 3 component models and AdS/CFT model • Need Midrapidity d+Au measurements to disentangle Cold Nuclear Effects from Hot Nuclear Effects to better understand heavier systems (Au+Au, Cu+Cu) For additional details, see posters by Zebo Tang and Chris Powell Chris Perkins

3. Motivation – Forward Rapidity • How can high-xF intrinsic heavy flavor happen? • Not from Gluon Splitting (extrinsic heavy flavor) • Heavy quarks are multi-connected to the valence quarks within a proton • Why does high-xF intrinsic heavy flavor matter? • Required for Diffractive Higgs production at the LHC • Provides a clear signal for Higgs production due to small background QED QCD • Can intrinsic heavy flavor expectations be tested experimentally? Phys.Rev. D73 (2006) 113005 • This is the first measurement of high-xF J/ψ at sqrt(s) > 62 GeV. Chris Perkins

4. STAR Detector • J/ψ detected at both Forward and Midrapidity through its decay channel to e+e- (~6% BR). • Significant reduction in background electrons expected at Midrapidity due to material removal prior to 2008 Run. Forward Meson Spectrometer Previously occupied by SVT/SSD Chris Perkins

5. Mid-rapidity d+AuRun 8 Chris Perkins

6. Mid-rapidity Electron Identification • Low-pT : • dE/dx cut with TPC • p/E cut with BEMC Minbias Trigger See poster by Chris Powell • High-pT : • Higher pT electron: TPC + BEMC + BSMD • BEMC – fast trigger to enrich high-pT electron sample • BSMD – electron/hadron separation • Lower pT electron: TPC only • BEMC High-Tower Trigger • See poster by Zebo Tang Chris Perkins

7. Low-PT Mid-rapidity J/ψ in d+Au • Efficiency corrected d+Au yield scaled by number of binary collisions and STAR p+p data • All centrality bins • Significance ~ 5.7 σ • Much better signal/background than previous low-pT J/ ψ measurements at STAR • Most central events (0-20%) • See poster by Chris Powell Chris Perkins

8. High-PT Mid-rapidity J/ψ in d+Au • Significance = 13 σ Triggered pT Spectrum • Significant observation of signal – corrections for yield still in progress • Efficiency corrected pT spectrum still in progress • See poster by Zebo Tang Chris Perkins

9. High-PT J/ψ -Hadron Correlations in d+Au 1) no near side correlation 2) strong near side correlation • Disentangle contributions to J/Psi production via correlations • From Monte Carlo studies, ref: PLB 200, 380(1988) and PLB 256,112(1991) • No significant near-side, high-pT J/ψ – hadron correlation in d+Au • May constrain feeddown contribution from B mesons • Can shed light on the J/ production mechanism • See poster by Zebo Tang Chris Perkins

10. Forward Rapidity p+pRun 8 Chris Perkins

11. Forward Meson Spectrometer (FMS) • 20x more acceptance than previous forward detectors at STAR • Full azimuthal coverage for 2.5 < η < 4 FPD FMS • Increased acceptance not only increases pion yields and kinematic range but also gives much higher geometric efficiency for high-xF J/ψ Geometric Efficiency: J/ψ xF Chris Perkins

12. FMS Analysis Procedure • Gain Calibrations : Done iteratively on a cell-by-cell basis by associating di-photon invariant mass peak with high tower cell and adjusting to PDG value for π0 mass. • Trigger :FMS High Tower + BBC Minbias (~ 6 pb-1 Sampled Luminosity) • Reconstruction : • Resolution smeared for simulation events to match detector resolution • All other reconstruction procedures and cuts were the same for data and simulation • 3-Cluster Analysis Overview : • χC → J/ψ + γ → e+ + e- + γ • Motivated by analysis done on ω → π0 + γ presented by Andrew Gordon at Moriond (see display) • For each group of 3 clusters within an event, associate the pair with reconstructed mass closest to 3.097 GeV/c2 with the J/ψ and the remaining cluster with the γ. • Provides additional arm with which to eliminate background Chris Perkins

13. FMS Minbias Simulations and Association Analysis • Fast J/ψ generator + full GEANT simulations • Data : • Plot includes < 1% of full data set • Simulation : • PYTHIA 6.222 + full GEANT simulations • 9.2 nb-1 Integrated Luminosity • Reconstructed quantities match generated quantities quite well • Full simulation models Mpair data very well Chris Perkins

14. Forward p+p J/ψ – 2-Cluster Analysis Reconstructed 2-cluster invariant mass Fit with Gaussian + Polynomial Gaussian Fit Parameters: • μ = 3.083 ± 0.017 GeV/c2 • σ = 0.028 ± 0.011 GeV/c2 • χ2/d.o.f. = 24.6/25 • Significance from fit • 2.1 σ Background Simulation: • Needs more statistics • Normalized to integral of data • Cuts Applied: • E_pair > 60.0 GeV • Zγγ < 0.7 • Isolation Radius: • 0.5 Eta-Phi Chris Perkins

15. Forward p+p J/ψ – 2-Cluster Analysis Reconstructed 2-cluster invariant mass • Fit with Gaussian + Offset • Gaussian Fit Parameters: • μ = 3.080 ± 0.020 GeV/c2 • σ = 0.082 ± 0.026 GeV/c2 • χ2/d.o.f. = 20.83/26 • Significance from fit • 4.5 σ • Cuts Applied: • E_pair > 60.0 GeV • Zγγ < 0.7 • Isolation Radius: • 0.4 Eta-Phi • pT_cluster > 1.0 GeV/c Chris Perkins

16. Forward p+p J/ψ – 3-Cluster Analysis • Reconstructed invariant mass of candidate χC → J/ψ + γ events • Peak Counts = 8.40 ± 2.88 • 2.9 σ Significance • μ = 2.97 ± 0.025 GeV • σ = 0.070 ± 0.025 GeV • χ2/d.o.f. = 0.7 with 14 points fit. • Significance depends on background model • 2.9 σ significance with currently estimated background. Chris Perkins

17. Summary • Mid-Rapidity : • Significant signal reported for high-pT and low-pT J/ψ in d+Au • RdAu consistent with Ncoll scaling for low-pT J/ψ • No significant near-side, high-pT J/ψ – hadron correlation in d+Au • Can constrain feeddown from B mesons • Forward Rapidity : • Significant signal reported for p+p collisions using 2-cluster analysis and new 3-cluster analysis • Provides first look at high-xFχC → J/ψ + γ feeddown • First observations of high-xF J/ψ at sqrt(s) > 62 GeV Chris Perkins

18. Outlook • Mid-Rapidity : • High-pT : • Efficiency corrections, RdAu, constrain B meson feeddown • Low-pT : • J/ψ mass spectrum in different centrality bins • Forward Rapidity : • Further analysis needed for p+p yield measurement : • Efficiency & Luminosity corrections • d+Au : • Nuclear effects in forward direction – new territory • 500 GeV : • Measure Upsilon and compare mass scaling • Towards understanding virtual heavy quark content in the proton Chris Perkins

19. Backup Slides Chris Perkins

20. Mid-Rapidity Low-pT Total Efficiency Chris Perkins

21. J/ψ Association Analysis Chris Perkins

22. Field Effects • Does the signal survive the field? • Radial and Azimuthal fields impart impulses in the Φ direction • These impulses are small and in opposite directions (they nearly cancel each other) • Field effects on our signal are small Chris Perkins

23. Forward p+p J/ψ – 2-Cluster Analysis Reconstructed 2-cluster invariant mass Fit with Gaussian + Polynomial Gaussian Fit Parameters: • μ = 3.083 ± 0.017 GeV/c2 • σ = 0.028 ± 0.011 GeV/c2 • χ2/d.o.f. = 24.6/25 • Significance from fit • 2.1 σ Background Simulation: • Needs more statistics • Normalized to integral of data • Cuts Applied: • E_pair > 60.0 GeV • Zγγ < 0.7 • Isolation Radius: • 0.5 Eta-Phi Chris Perkins

24. Forward p+p J/ψ – 2-Cluster Analysis Reconstructed 2-cluster invariant mass • Fit with Gaussian + Offset • Gaussian Fit Parameters: • μ = 3.080 ± 0.020 GeV/c2 • σ = 0.082 ± 0.026 GeV/c2 • χ2/d.o.f. = 20.83/26 • Significance from fit • 4.5 σ • Cuts Applied: • E_pair > 60.0 GeV • Zγγ < 0.7 • Isolation Radius: • 0.4 Eta-Phi • pT_cluster > 1.0 GeV/c Chris Perkins

25. Mid-rapidity Cuts • Low-pT – TPC + BEMC • pT track > 1 GeV/c • 3 < p < 4 GeV/c tracks • |nσe| < 3, |nσp| > 2.5, |nσpi| > 2.5, |nσK| > 2.5 • p/E < 2.3 • High-pT – • nσe > -2 Chris Perkins