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Salvatore Fazio (Brookhaven National Lab) for the STAR Collaboration DIS 2014 – April 28 to May 2 2014 Transverse single-spin asymmetries in W ± and Z.

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Presentation on theme: "Salvatore Fazio (Brookhaven National Lab) for the STAR Collaboration DIS 2014 – April 28 to May 2 2014 Transverse single-spin asymmetries in W ± and Z."— Presentation transcript:

1 Salvatore Fazio (Brookhaven National Lab) for the STAR Collaboration DIS 2014 – April 28 to May 2 2014 Transverse single-spin asymmetries in W ± and Z 0 bosons production in p+p collisions at RHIC

2 May 1, 2014S. Fazio - DIS 20142 Plan of the talk  Physics motivations  The W ± selection and A N measurement  The Z 0 selection and A N measurement  Future plans  Conclusions

3 3 Collinear/ twist-3 Q,Q T >>  QCD p T ~Q Transverse momentum dependent Q>>Q T >=  QCD Q>>p T Intermediate Q T Q>>Q T /p T >>  QCD Sivers fct. Efremov, Teryaev; Qiu, Sterman May 1, 2014S. Fazio - DIS 2014 Motivations QCD:QCD: Sivers DIS = - Sivers (DY or W or Z) A N (direct  ) measures the sign change through Twist-3 DIS:  q scattering attractive FSI pp: annihilation repulsive ISI critical test for our understanding of TMD’s and TMD factorization The much discussed sign change of the Sivers’ function TMDs need 2 scales Q 2 and p t Remember pp: most observables one scale Exception: DY, W/Z Twist-3 needs only 1 scale Q 2 or p t But should be of reas. size. Applicable to most pp observables A N (  0 /  /jet) Goal: measure sign change and pin down TMD-evolution by measuring A N for , W ±, Z 0, DY Q  QCD Q T /P T << Q T /P T ANAN

4 May 1, 2014S. Fazio - DIS 20144 Motivations  Unpolarized asymmetries: Quantitative calculation of Pauli blocking does not explain ratio  Non-pQCD effects are large for sea quarks  Polarized asymmetries: valence quarks distributions well determined from DIS measurements The W ± /Z 0 transverse asymmetry:  Very high Q 2 -scale (~ W/Z boson mass)  No fragmentation function  Asymmetry from lepton-decay is diluted  Full kin. reconstruction of the boson needed Processes: W  e v e Z 0  e + e − x

5 May 1, 2014S. Fazio - DIS 2014 M. G. Echevarria, A. Idilbi, Z-B Kang, and I. Vitev arXiv:1401.5078 Motivations 5 Sea quarks are mostly unconstrained but they can give a relevant contribution! 0 < p T <3 GeV Error bands use positivity bounds for the sea quarks  Z 0 easy to reconstruct (but small cross section)  W kin. can be reconstructed from the hadronic recoil (first time at STAR)  HERMES, COMPASS and JLab data not very sensitive to the sea quark Sivers because of their limited x-range  W ± data can constrain the sea-quark Sivers Uncertainties not shown

6 May 1, 2014S. Fazio - DIS 20146 The STAR detector @ RHIC Solenoid Magnet (0.5 T) Time Projection Chamber (|η| < 1.4) Barrel EMCAL (|η| < 1)

7 May 1, 2014S. Fazio - DIS 20147 Strategy Ingredients for the analysis Isolated electron neutrino (not measured directly) Hadronic recoil  Select events with the W-signature  Isolated high P T > 25 GeV electron  Hadronic recoil with total P T > 18 GeV  Neutrino transverse momentum is reconstructed from missing P T  Neutrino’s longitudinal momentum is reconstructed from the decay kinematics Ingredients for the analysis Isolated electron Ingredients for the analysis Isolated electron neutrino (not measured directly) Ingredients for the analysis

8 May 1, 2014S. Fazio - DIS 2014 Monte Carlo  PYTHIA reconstructed trough GEANT simulated STAR detector  Perugia tune with hard P T > 10 GeV  PYTHIA embedded into real zero- bias pp events Data sample pp – transverse (collected in 2011) @ √500 GeV Luminosity: ~ 25 pb -1 Events triggered in Barrel EMCAL Data & MC Background W  tv t  ev e v t Z  ee QCD events 8 Signal W  ev e

9 MC May 1, 2014S. Fazio - DIS 2014 Electron identification Isolation: (P track +E cluster ) / Σ[P tracks in R=0.7 cone] > 0.8 Imbalance: no energy in opposite cone (E<20 GeV) E T > 25 GeV Track |η| < 1 |Z-vertex|<100 cm Charge separation (avoids charge misidentification): 0.4 < |Charge (TPC) x E T (EMC) / P T (TPC)| < 1.8 Signed P T balance > 18 GeV (rejects QCD Background) We calculate energy from the cluster DATA SIGNAL QCD 9

10 May 1, 2014S. Fazio - DIS 2014 Background estimation  Positive-charge signal 1216 events  Z  ee  W +  tv t Background estimated via MC normalized to data lumi 10  Negative-charge signal 332 events  Z  ee  W -  tv t W + sample Z 0 -> ee = 10.71 events [B/S = 0.88%] W + -> tv t = 22.92 events [B/S = 1.88%] W − sample Z 0 -> ee = 9.77 events [B/S = 2.94%] W - -> tv t = 4.62 events [B/S = 1.39%]

11 May 1, 2014S. Fazio - DIS 2014 QCD background estimation Data-driven QCD background estimation Reverse of P T -balance cut [PT-balance < 15 GeV]  Selects QCD events Plot lepton-P T > 15 GeV QCD sample normalized to the first P T -bin [15-19 GeV] W + sample QCD = 19.37 events [B/S = 1.59%] final sample P T > 25 GeV 11 final sample P T > 25 GeV W − sample QCD = 11.30 events [B/S = 3.40%] COMMENTS: Backgrounds under control! Z -> e + e − expected to have a comparable asymmetry

12 May 1, 2014S. Fazio - DIS 2014 W P T reconstruction We calculate the recoil summing up all tracks and trackless electromagnetic clusters Matching track is a track which extends to the BEMC and matches a firing tower (< 7 cm) Trackless tower is a firing tower in the BEMC with no matching tracks and Energy > 200 MeV Recoil is calculated summing the momenta of all tracks which do not belong to the electron candidate + all firing trackless towers 12 In transverse plane: Recoil reconstructed using tracks and towers: Part of the recoil not within STAR acceptance  MC correction applied

13 May 1, 2014S. Fazio - DIS 201413 Monte Carlo correction The Correction method – Read recoil P T bin from data Project correction factor for corresponding P T -bins Normalize the projection distribution to 1 Pick a correction value sampled from the projection distribution MC MC test: After MC correction  very good agreement with RhicBOS and PYTHIA predictions

14 May 1, 2014S. Fazio - DIS 201414 We add to our selection: Track-P T in the recoil > 0.2 GeV Total recoil-P T > 0.5 GeV W P T – Data/MC GOOD data/MC agreement after P T correction

15 May 1, 2014S. Fazio - DIS 201415 W P Z reconstruction W longitudinal momentum (along z) can be calculated from the invariant mass. Currently we assume constant M W (for W produced on shell) Neutrino longitudinal momentum component from quadratic equation Two solutions! Smaller |Pz|  first solution Larger |Pz|  other solution BOTH the first and the other solution can have misreconstructed events!

16 May 1, 2014S. Fazio - DIS 2014 FIRST SOLUTION for Pz |P L | < 50 GeV  < 40 % misreconstructions 16 How do we estimate the fraction? Answer: we take the # events where Pz is reconstructed within +/- 30 GeV NOTE: We only use the first solution. This can be improved at a later stage. We cut at |Pz| < 50 GeV  |W-y| < 0.6 to minimize misreconstructions We select the first solution  better Fraction of correctly reconstructed events

17 May 1, 2014S. Fazio - DIS 201417 MC challenge - systematics  Tables (W rapidity-P T bins) for A N prediction with evolution given by Z-B Kang [arXiv:1401.5078]  Use PYTHIA MC prediction for W − (the A N prediction is always positive)  Assign each prediction value from the tables according to the generated values of W-rapidity and P T  After the event is fully reconstructed we look at the P T distributions of A N GeneratedReconstructed  We fit a Gaussian distribution and compare the means  We rely on the fact that the input asymmetry has the same dependence as the data The same is done for W-P T -0.2 < y < 0.2

18 May 1, 2014S. Fazio - DIS 201418 W Asymmetry First we calculate the asymmetries for each beam separately Then we combine the two asymmetries We fit sin( ϕ ) modulation with phase = π/2 Average RHIC polarization for 2011 transverse p-p data  P = 53% We use the “square root formula” to cancel dependencies on geometry and luminosity Asymmetries measured:  Signal sample asymmetry In backup slides:  Geometrical effects asymmetry  Luminosity effects asymmetry

19 May 1, 2014S. Fazio - DIS 201419 A N vs W-rapidity

20 May 1, 2014S. Fazio - DIS 201420 A N vs W-P T

21 May 1, 2014S. Fazio - DIS 201421 Z 0 production Clean experimental momentum reconstruction Negligible background electrons rapidity peaks within tracker accept. (|  |< 1) Statistics limited Z 0 boson selection criteria Two tracks each pointing to a cluster (no isolation requirements) E T > 25 GeV for both candidates The two candidate tracks have opposite charge |Zvertex|< 100 cm Invariant Mass within ± 20% from the nominal M Z 2011 pp-tran. ~25 pb -1 : 50 events survive the selection

22 May 1, 2014S. Fazio - DIS 201422 Z 0 Asymmetry A N measured in a single y, P T bin

23 May 1, 2014S. Fazio - DIS 201423 RHIC is capable of delivering ~900 pb -1 transverse p-p in 2016 Possibility for significantly measure A N for Ws within a few % in several W-P T, y bins. Syst. from 2011 analysis rely on predictions and can be improved with more data Possibility to measure the very clean Z 0 channel. Goal: measure sea-quark Sivers and pin down TMD-evolution How?  Measure A N for , W ±, Z 0, DY  DY and W ±, Z 0 give Q 2 evolution  W ± give sea-quark Sivers  All three A N give sign change...and the future?

24 May 1, 2014S. Fazio - DIS 2014 Summary First measurement of A N for W ± and Z 0 production at RHIC by reconstruction of the boson kinematics, using a sample of 25 pb -1 transverse p-p data @ √500 GeV collected by STAR Systematic uncertainties are constrained within < 15% A N in the Z 0 boson channel  clean & background free, but need lumi We have a proof-of principle  A N for Ws can be measured at STAR, new RHIC data (can deliver up to L~900 pb -1 ) can give statistical significance to test the Sivers’ sign change and pin down TMD evolution RHIC run 2016: STAR can have access to A N for , W ±, Z 0, DY in a single experiment, simultaneously! 24

25 May 1, 2014S. Fazio - DIS 201425 BACKUP

26 May 1, 2014S. Fazio - DIS 201426 Determine the fraction for correctly reconstructed events (for both solutions) FIRST SOLUTION OTHER SOLUTION W P Z reconstruction

27 May 1, 2014S. Fazio - DIS 201427 ~11% of reco. events migrate more than one y-bin ~2% of reco. events migrate more than one y-bin ~11% of reco. events migrate more than one y-bin Distributions of y-Reco in each bin of y-Gen Three W-y bins = {-0.6; -0.3; 0.3; 0.6} Rapidity binning bin1 survival probability = 52% bin2 survival probability = 63% bin3 survival probability = 54%

28 May 1, 2014S. Fazio - DIS 201428 W+W- W+W- W plain asymmetry

29 May 1, 2014S. Fazio - DIS 201429 Z 0 plain asymmetry -6 < η < 6

30 May 1, 2014S. Fazio - DIS 201430 W+W- Geometrical Asymmetry W+ W-

31 May 1, 2014S. Fazio - DIS 201431 W+W- Luminosity Asymmetry W+ W-

32 May 1, 2014S. Fazio - DIS 201432 Z 0 lepton candidates Lepton candidate go to central rapidity and have large P T

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