xiaoyang gong for phenix collaboration
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Xiaoyang Gong for PHENIX Collaboration. Phase diagram. A central goal in nuclear physics is to map out the QCD phase diagram. RHIC experiments at 200GeV beam energy showed that QGP is created and cools down to hadron gas via a crossover transition. - PowerPoint PPT PresentationTRANSCRIPT
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Xiaoyang Gong for PHENIX Collaboration
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Phase diagram 2
A central goal in nuclear physics is to map out the QCD phase diagram.
RHIC has embarked an beam energy scan (BES) program to:
a)Locate the QGP-Hadron Gas phase boundary and critical point.b)Obtain properties of nuclear matter in each phase.
RHIC experiments at 200GeV beam energy showed that QGP is created and cools down to hadron gas via a crossover transition.
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Alver, Roland, Phys.Rev.C81, 054905
Probe Phase Diagram 3
From Yadav, WWND2011
What probes do we have to study nuclear matter created at RHIC?
SpectraHBTFlow observablesParticle azimuthal correlation, jetFluctuations
Focus of this talk
Eccentricity of initial geometry leads to a non-trivial profile of particle azimuthal distribution (dN/dφ).
Characterized by Fourier Coefficients vn.
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Why Flow Measurement? 4
Phys.Rev.Lett.97, 152303 (2006)
Flow measurement at each of the beam energies could help us answer the following questions:At what energy flow at partonic level is turned off?
The initial geometry of nuclear matter created at different energies?
Specific viscosity (η/s) at these beam energies?
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Independent Measurements 5
Gong and Ark use event-plane method: reconstruct event planes in the forward detectors; measure central arm particle azimuthal distributions relative to event plane.
Gu uses long-range correlation method: Fourier decomposition of correlation functions built with one particle from central arm and the other from forward detectors.
Remarkable agreements between two methods!
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Precise and Robust Measurement 6
Reaction plane detectorRXNINN (1.5<||<2.8)RXNOUT (1.0<||<1.5)
Muon piston CalorimeterMPC (3.1<||<3.9)
Beam-beam counterBBC (3.1<||<3.9)
RXNRXN
BBC/MPC BBC/MPC
Forward detectors at different η:
Measurements with different forward detectors help us control systematics
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Charge Hadron v2: 39, 62 and 200GeV 7
v2 show saturation for beam energy 39-200GeV.
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Preliminary, STAR, PHENIX and E895 data
v2
v2’s at 7.7GeV are significantly lower than those at 39, 62 and 200GeV
Excitation Function 8
Saturation: indicate a Soft EOS?
Significant lower v2 below 39GeV
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Higher Order Harmonics: v3 and v49
Significant attention has been given to the higher order harmonics recently.
Measurement at 200GeV shows that higher order harmonics could provide additional constraints on initial geometry models.
Do v3 and v4 saturate at 62 and 39GeV as v2 did?
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Charge Hadron vn(Ψn): 62GeV 10
Sizable v3 and v4 signals compared to v2.
vn(Ψn)
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Charge Hadron vn(Ψn): 39GeV 11
Sizable v3 and v4 signals as well.
vn(Ψn)
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Beam Energy Dependence of v3(Ψ3) 12
v3(Ψ3)
v3(Ψ3)
PHENIX Preliminary
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Beam Energy Dependence of v4(Ψ4) 13
v4(Ψ4) show saturation within systematic errors as well.
v4(Ψ4)
v4(Ψ4)
PHENIX Preliminary
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Saturation at LHC energy 14
vn(Ψn) vn(Ψn)
vn has been measured up to 6th order on experiments at LHC with great precision. How do vn measured at RHIC compared to those at LHC?
v3, v4 are saturated above 39GeV, even at LHC energy.
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Identified Charge Hadron v215
Does quark number scaling hold at 62 and 39GeV?
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v2 at Intermediate pT16
Phys. Rev. Lett. 105, 142301 (2010)
So far we focused on low pT (<3GeV) region, what about v2 at higher pT?
At this intermediate pT region, v2 represents the combined effect of hydrodynamics and jet energy-loss.
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Summary 17
Measurements suggest similar initial geometry and dynamic evolution of nuclear matter above 39GeV.
Preliminary, STAR, PHENIX and E895 data
Smooth dropping of v2 is observed below 39GeV.
Data taken at 19.6GeV this year would help us check the “gap” in the transition region.
vn(Ψn)
?
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Backup
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v4(Ψ2)
Since Ψ2 and Ψ4 are correlated, we observe sizable v4(Ψ2) (about half of v4(Ψ4)).
Beam Energy Dependence of v4(Ψ2) 19
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V3 20
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PID v2 saturation 21
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62GeV