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Distribution of Drell-Yan Dielectron Pairs at CDF Run II

This paper presents the measurement of the distribution of Drell-Yan dielectron pairs at CDF Run II. The study includes event selection, acceptance and efficiency, background estimation, and systematic uncertainties. The preliminary results show consistent results in both positive and negative rapidity regions.

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Distribution of Drell-Yan Dielectron Pairs at CDF Run II

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  1. d/dy Distribution of Drell-Yan Dielectron Pairs at CDF Run II Jiyeon Han (University of Rochester) For the CDF Collaboration DPF + JPS October, 30, 2006 Honolulu, Hawaii

  2. Chicago  p p 1.96 TeV Booster p CDF DØ Tevatron p p source Main Injector & Recycler Outline • Introduction • CDF Run II detector • Event selection • Acceptance and efficiency • Silicon tracking efficiency • Background estimation • Systematic uncertainty • Run II result • Summary Jiyeon Han (University of Rochester)

  3. Central electron ||  1.1  = 1.0 plug electron ||  1.1  = 2.8  = 3.6  = -ln(tan(/2)) CDF Run II Detector • Plug calorimeter covers high  region(~ 3.6) • Silicon track covers || < 2.8 • Silicon tracking reduces background contamination Jiyeon Han (University of Rochester)

  4. Feynman Diagram Zpp Zcp Zcc Introduction • Parton momentum fractions (x1,2) determine rapidity (y) of Z boson • The measurement of high y region probes high xregion • Z boson decays to two forward electron corresponds to high y • d/dy measurement tests PDF predictions Jiyeon Han (University of Rochester)

  5. Data set • Data sample : ~1.1 fb-1 • Inclusive single central electron trigger • Two electron trigger (central or forward) • Trigger efficiency measured as a function of electron ET • Overall trigger efficiency ~ 100 %  Total trigger efficiency Zcc : 1.0 Zcp : 0.9940.001 Zpp : 0.9950.001 Jiyeon Han (University of Rochester)

  6. central plug central Selection • Z selection with two central electrons : Zcc • Kinematic selection : ET 25 GeV , ||1.1 • Two electrons with tight and loose ID • Opposite charge electrons required • Z selection with a central and forward electron : Zcp • Kinematic selection : ET 20 GeV ||1.1 for central, 1.2  ||2.8 for plug • One tight central electron and one plug electron • Z selection with two forward electrons : Zpp • Kinematic selection : ET 25 GeV , 1.2  ||  2.8 • Two plug electrons • Same side events required • One leg must have a silicon track Jiyeon Han (University of Rochester)

  7. Zcc Zcp Zpp Mass and Rapidity CDF preliminary result Mass window : 66 < M < 116 GeV Probe high y region ( ~ 2.9 ) Jiyeon Han (University of Rochester)

  8. Acceptance and Efficiency • Acceptance  Efficiency in rapidity • A  E is flat up to y ~ 2.0 and non-zero to y ~ 2.9 by adding PP region • Geometric and kinematic acceptances modeled using Pythia MC and GEANT detector simulation • MC tuned to data  Energy resolution and scale  Electron ID efficiency Jiyeon Han (University of Rochester)

  9. |zvtx|15 15|zvtx|30 30|zvtx|60 |zvtx|60 Silicon tracking efficiency I • One Silicon track required in Zpp to reduce the background • There is a discrepancy between the data and MC silicon track finding efficiencies • Data/MC efficiency ratio (scale factor) as a function of Z vertex and  • Scale factors applied to MC on event by event basis Jiyeon Han (University of Rochester)

  10. Silicon tracking efficiency II • Measure the effects of the selection efficiency of requiring at least one silicon track as a function of the boson rapidity in Zpp • Determined from corrected MC • Total tracking efficiency is 0.845 Jiyeon Han (University of Rochester)

  11. Isolation E Backgrounds for Z/* : QCD • Largest background : QCD dijets • Magnitude obtained from fit to electron isolation distribution • Isolation defined as energy contained in a R=0.4 cone around an electron minus the energy of the electron itself • Fit isolation distribution for both signal and background contributions • Extrapolate the background from high Isolation tail into the signal region Events Jiyeon Han (University of Rochester)

  12. Backgrounds for Z/* : EWK • EWK background processes • Estimated using PythiaMC Zcc data Zcp data Zpp data Combined data Ewk background Dijet background Jiyeon Han (University of Rochester)

  13. Systematic study • Systematic uncertainties determined for • Detector material modeling • Background estimates • Electron identification efficiencies • Silicon tracking efficiency Largest systematic uncertainties associated with measurement of silicon tracking efficiencies Jiyeon Han (University of Rochester)

  14. CDF Run II preliminary d/dy distribution I • d/dy distribution of Z/* (positive and negative rapidity region) • (y>0) : 265.31.5(stat.)1.5(sys.) pb (y<0) : 266.61.4(stat.)1.4(sys.) pb • No PDF or luminosity uncertainties included •  of positive and negative rapidity is consistent Jiyeon Han (University of Rochester)

  15. CDF Run II preliminary d/dy distribution II • d/dy distribution of Z/* • NNLO calculation with NLO CTEQ6.1 PDF •  (Zee) : 265.9± 1.0(stat.)1.1(sys.)pb • No PDF or luminosity uncertainties included Jiyeon Han (University of Rochester)

  16. d/dy distribution (data/theory) • NLO calculation with NLO MRST PDF No PDF or L uncertainties included in data Theory prediction scaled to measured  (Z) • NNLO calculation with NLO CTEQ6.1 PDF CDF Run II preliminary • NLO calculation with NLO CTEQ PDF CDF Run II preliminary NNLO calculation with NLO CTEQ6.1 PDF describes data best CDF Run II preliminary Jiyeon Han (University of Rochester)

  17. Summary • We measure d/dy distribution of Z/*e+e- up to y ~ 2.9 • Total cross section  265.9  1.0(stat.)  1.1(sys.) pb • No PDF or luminosity uncertainties included • Measured d/dy shape best matches NNLO calculation with NLO CTEQ6.1 PDF • need to reduce the systematic uncertainty from silicon tracking Jiyeon Han (University of Rochester)

  18. Backup slide Jiyeon Han (University of Rochester)

  19. RunI result • PDF predictios • LO CTEQ4 PDF • NLO CTEQ4 PDF • d quark enhanced modified NLO CTEQ4 PDF • NLO gluon resummated calculation with CTEQ4 PDF • not enough to make a distinction better PDF Jiyeon Han (University of Rochester)

  20. Z mass and Et distribution • Z mass and electron Et distribution (data, MC) Jiyeon Han (University of Rochester)

  21. Z mass and Et distribution of Zcp • Z mass and electron Et distribution (data, MC) Et,c Et,p Eta,c Eta,p Jiyeon Han (University of Rochester)

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