Ilia Ravinovich for the PHENIX Collaboration

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Presentation transcript:

Di-electron measurements with the Hadron Blind Detector in the PHENIX experiment at RHIC Ilia Ravinovich for the PHENIX Collaboration Weizmann Institute of Science INPC, Firenze, Italy, June 2-7, 2013 I. Ravinovich INPC 2013

Outline Published PHENIX results Hadron Blind Detector (HBD) Preliminary results with the HBD Recent progress on the analysis front Summary I. Ravinovich INPC 2013

PHENIX dilepton program PHENIX has measured the dielectron spectrum over a wide range of mass and transverse momentum The program includes a variety of collision systems at 200 GeV: p+p, with and without HBD; d+Au without HBD; Cu+Cu without HBD; Au+Au, with and without HBD; I. Ravinovich INPC 2013

Dilepton continuum in p+p collisions Phys. Lett. B 670, 313 (2009) Data and cocktail of known sources represent pairs with e+ and e- in PHENIX acceptance Data are efficiency corrected Excellent agreement of data and hadron decay contributions within systematic uncertainties I. Ravinovich INPC 2013 4 4

Estimate of expected sources, “Cocktail” Hadron decays: Fit π0 and π± data p+p or Au+Au for other mesons η, ω, ρ, ϕ, J/Ψ etc use mT scaling and fit normalization to existing data where available Heavy flavor production: sc= Ncoll x 567±57±193 mb from single electron measurement Hadron data follows “mT scaling” Predict cocktail of known pair sources I. Ravinovich INPC 2013

Au+Au dilepton continuum PRC 81, 034911 (2010 Strong excess of dielectron pairs at low masses: 4.7 +/- 0.4 (stat) +/- 1.5 (syst) +/- 0.9 (model) I. Ravinovich INPC 2013 6 6

Comparison to theoretical models All models and groups that successfully described the SPS data fail in describing the PHENIX results I. Ravinovich INPC 2013

The goal of the HBD is to improve the signal significance! Motivation The excess at masses 0.2-0.7 GeV/c2 is 4.7 +/- 0.4 (stat) +/- 1.5 (syst) +/- 0.9 (model) It is mainly concentrated in the central collisions. But in this low mass range we have a very poor S/B ratio (~1/200), especially in the central collisions. So, the results are limited by this large uncertainty due to the huge combinatorial background. Dielectrons are an interesting probe of the the RHIC medium… The goal of the HBD is to improve the signal significance! I. Ravinovich INPC 2013

Key Challenge for PHENIX: Pair Background No background rejection  Signal/Background  1/100 in Au-Au Combinatorial background: e+ and e- from different uncorrelated source unphysical correlated background: track overlaps in detectors Correlated background: e+ and e- from same source but not “signal” “Cross” pairs “Jet” pairs π0 e+ e- γ X I. Ravinovich INPC 2013

How can we spot the background? Typically only 1 electron from a pair falls within the PHENIX acceptance: the magnetic field bends the pair in opposite directions. some spiral in the magnetic field and never reach tracking detectors. To eliminate these problems: detect electrons in field-free region need >90% efficiency ~12 m I. Ravinovich INPC 2013

Separating signal from background π φ pads relativistic electrons Mass spectrum from pion Dalitz decays peaked around 2me Spectrum from photon conversion tightly peaked around 2me Heavier meson decays have large opening angles Opening angle can be used to cut out photon conversion and Dalitz decays must be able to distinguish single hits (“interesting” electrons) from double hits (Dalitz and photon conversion). I. Ravinovich INPC 2013

HBD design and performance NIM A646, 35 (2011) Single electron Windowless CF4 Cherenkov detector GEM/CSI photo-cathode readout Operated in B-field free region Goal: improve S/B by rejecting conversions and π0 Dalitz decays Successfully operated: 2009 p+p data 2010 Au+Au data Hadron blindness e-h separation Figure of merit: N0 = 322 cm-1 20 p.e. for a single electron Preliminary results: S/B improvement of ~5 wrt previous results w/o HBD Double electron I. Ravinovich INPC 2013

Run-9 p+p dileptons with the HBD Factor of 5-10 improvement in S/B ratio this improvement is achieved using HBD only as an additional eID detector more should be possible by using a double rejection cut Fully consistent with published result Provide crucial proof of principle and testing ground for understanding the HBD I. Ravinovich INPC 2013

Run-10 Au+Au dileptons with the HBD Peripheral Semi-peripheral Semi-central + I. Ravinovich INPC 2013

Run-10 data with HBD: data/cocktail Hint of enhancement for more central collisions Not conclusive given the present level of uncertainties LMR (m = 0.15 – 0.75 GeV/c2) IMR (m = 1.2 – 2.8 GeV/c2) Similar conclusions for the IMR I. Ravinovich INPC 2013

Recent progress on the analysis front Component-by-component background subtraction, namely: Subtract combinatorial background using mixed event. Subtract correlated cross pairs generated by MC. Subtract correlated jet pairs using PYTHIA simulations. Improved electron sample purity. Increased statistics. I. Ravinovich INPC 2013

Improved electron sample purity Improved RICH ring algorithm Issue: parallel track point to the same ring in RICH. Hadrons can leak in. New algorithm forbids a ring to be associated with multiple tracks  associate with electron-like tracks Including ToF information PbSc s=450 ps, ToF East s=140 ps π MC shows: electron sample purity > 90% can be achieved in the most central events I. Ravinovich INPC 2013

Summary Preliminary results on dielectrons in p+p and Au+Au collisions at 200 GeV in three centrality bins with Hadron Blind Detector in PHENIX. These results are consistent with previously published PHENIX results without HBD. The next step is to complete the analysis with the recent newly developed tools which will allow us to release the results for the most central events. I. Ravinovich INPC 2013

Backup slides I. Ravinovich INPC 2013

Centrality dependence of the enhancement This I not exactly the published figure. The figure in the paper is not of good quality In the IMR the normalized yield shows no significant centrality dependence In the LMR the integrated yield increases faster with the centrality of the collisions than the number of participating nucleons I. Ravinovich INPC 2013

pT dependence of low mass enhancement Au+Au p+p 0<pT<8.0 GeV/c 0<pT<0.7 GeV/c 0.7<pT<1.5 GeV/c 1.5<pT<8 GeV/c Low mass excess in Au-Au concentrated at low pT! I. Ravinovich INPC 2013 21

mT distribution of low-mass excess Excess present at all pair pT but is more pronounced at low pair pT PHENIX The excess mT distribution exhibits two clear components It can be described by the sum of two exponential distributions with inverse slope parameters: T1 = 92  11.4stat  8.4syst MeV T2 = 258.3  37.3stat  9.6syst MeV I. Ravinovich INPC 2013

HBD installed in PHENIX IR HBD West HBD East I. Ravinovich INPC 2013

Analysis details of Au+Au with HBD Strong run QA and strong fiducial cuts to homogenize response of the central arm detectors over time large price in statistics and pair efficiency Two parallel and independent analysis streams: provide crucial consistency check Stream A HBD: underlying event subtraction using average charge per pad Neural network for eid and for single/double electron separation Correlated background (cross pairs and jets) subtracted using acceptance corrected like-sign spectra Stream B HBD: underlying event subtraction using average charge in track projection neighborhood Standard 1d cuts for both eid and for single/double electron separation Correlated background subtracted using MC for the cross pairs and jet pairs Results shown here are from stream A I. Ravinovich INPC 2013

Differences in runs with and without HBD Data: Different magnetic field configuration: Run-9 (p+p) and Run-10 (Au+Au) with HBD: +- field configuration all other runs: ++ field configuration larger acceptance of low pT tracks in +- field More material due to HBD: more J/Ψ radiative tail We can compare results in three centrality bins: 20- 40%, 40-60% and 60-92% Cocktail: MC@NLO for open heavy flavor (c,b) contribution instead of PYTHIA MC@NLO(1.2-2.8) = PYTHIA(1.2-2.8) * 1.16 I. Ravinovich INPC 2013

Comparison of run-10 to published run-4 results LMR (m = 0.15 – 0.75 GeV/c2) Run 10 – Data/ cocktail Run 4 – Data/ cocktail Phys Rev C81, 034911 (2010) Consistent results I. Ravinovich INPC 2013

Comparison of run-10 to published run-4 results IMR (m = 1.2 – 2.8 GeV/c2) Run 10 – Data/ cocktail Run 4 – Data/ cocktail c,b yields based on MC@NLO MC@NLO = PYTHIA * 1.16 Consistent results I. Ravinovich INPC 2013

Background subtraction (at QM2012) p+p: all bckg = relative acceptance corrected like-sign pairs Au+Au: combinatorial background (mixed events); correlated background (relative acceptance corrected like-sign pairs) This method does not provide precision needed (~0.1%) for central Au+Au collisions  fluctuations due to dead areas, sector inefficiencies, statistics  apply component by component subtraction I. Ravinovich INPC 2013

Component by component subtraction Combinatorial background (mixed event) Cross-pairs (EXODUS) Jet pairs (PYTHIA) I. Ravinovich INPC 2013