Fluctuations and Correlations at

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Presentation transcript:

Fluctuations and Correlations at RHIC and the LHC Huichao Song 宋慧超 Peking University QCD 相结构与集体效应大连, 2017年6月26-30日 June. 28, 2017

Correlations & fluctuations S.Bass QGP Correlations & fluctuations -Correlated fluctuations near the QCD critical point -Non-critical (thermal) fluctuations

Initial state fluctuations & final state Correlations

Observables for initial state fluctuations (I) C. Gale, PRL2013 Xu, Li & Song, PRC 2016 -Vn (integrated, differential, PID ) are nice described by e-b-e hydrodynamics and hybrid model

Observables for initial state fluctuations (II) Zhu, Zhou, Xu, Song, PRC 2017 Various flow data reflect the information of initial state fluctuations, some of them provide strong constraint for initial conditions Zhao, Xu, Song, 1703.10792

Correlated fluctuations near the QCD critical point Initial State Fluctuations -QGP fireball evolutions smear-out the initial fluctuations RHIC BES -uncorrelated (in general) Fluctuations near the critical point -dramatically increase near Tc -Strongly correlated -Static vs dynamical critical fluct.

Static critical fluctuations

Theoretical predictions on critical fluctuations Stephanov PRL 2009 Critical Fluctuations of particles : Higher cummulants (ratios) of net protons are sensitive observables to probe the QCD critical point

STAR BES: Cumulant ratios STAR PRL 2014 Xiaofeng Luo CPOD 2014 PT=(0.4-2) GeV PT=(0.4-0.8) GeV -Non-monotonic behavior, large deviation from the Poisson baseline How to systematically describe the collision energy, centrality and acceptance cut dependence ?

Freeze-out Scheme near the Critical Points Hydro freeze-out surface Jiang, Li & Song, PRC 2016 Particle emissions in traditional hydro Particle emissions near Tcr

For static & infinite medium: --the results in Stephanov PRL09 are reproduced

CORRELATED particle emissions along the freeze-out surface Hydro freeze-out surface For simplicity: We assume that the correlated sigma field only influence the particle emissions near Tc, which does not influence the evolution of the bulk matter -- Static critical fluctuations along the freeze-out surface

Comparison with the experimental data -Acceptance dependence -Cumulants & cummulant ratios

Static critical fluctuations Acceptance dependence Jiang, Li & Song, PRC2016 STAR Data Static critical fluctuations Poisson Baselines -Static critical fluctuations can qualitatively explain the acceptance dependence of the STAR data

Cumulants of net protons Jiang, Li & Song, PRC2016 Net Protons 0-5% PT=(0.4-2) GeV PT=(0.4-0.8) GeV Static critical fluctuations give positive contribution to C2 , C3; well above the poisson baselines, can NOT explain/describe the C2 , C3 data

Dynamical Critical Fluctuations -Dynamical universality class -Static (equilibrium) universality class -QCDmatter, 3-D Ising model, gas-liquid -whether or not the order parameter is conserved -other conserved quantities in the system -Model A: non-conserved order parameter -Model B: conserved order parameter; -Model H: conserved energy and baryons density, non-conserved order parameter … … … ….

Effects from dynamical evolutions -Model A S. Mukherjee, R. Venugopalan, Y. Yin, PRC92 (2015) sign of non-Gaussian cumulants can be different from equilibrium one

Dynamical critical fluctuations of the sigma field Langevin dynamics: with effective potential from linear sigma model with constituent quarks -Model A Jiang, Wu, Song, NPA 2017, paper in preparation -The signs of C3 & C4 are different from the equil. ones due to memory effects -in the near future: maping with 3D Ising model; extend to model B; dynamical universal behavior

Dynamical critical fluctuations of the sigma field Langevin dynamics: with effective potential from linear sigma model with constituent quarks -Model A Jiang, Wu, Song, NPA 2017, paper in preparation -Super cooling & bubble formations: C3 & C4 are largely enhanced compared with the equil. ones

Non-Critical (Thermal) Fluctuations

-Where does the Poisson baselines come from? -Poisson fluctuations are widely used in experimental analysis and theoretical study. -Where does the Poisson baselines come from?

Hadron Resonance Gas Model -Grand canonical ensemble(GCE) -With Boltzmann approximation -The susceptibilities Poisson Baselines! Cleymans J, Kämpfer B, Kaneta M, et al.. Phys. Rev. C, 2005, 71(5): 054901. Garg P, Mishra D K, Netrakanti P K, et al. Phys. Lett. B, 2013, 726(4): 691-696.

Improved Hadron Resonance Gas Model [Nahrgang, et al. EPJC75 (2015) no.12, 573] -Acceptance cut: -Resonance decays:

Improved Hadron Resonance Gas Model [Nahrgang, et al. EPJC75 (2015) no.12, 573] -Acceptance cut: -Resonance decays: -For static and equilibrium medium -Not apple to apple comparison with the data - A realistic heavy ion collision: dynamical evolutions - late hadronic evolution: Chemical and thermal equilibrium can not be maintained

Multiplicity fluctuations of (net) Charges and (net) protons from iEBE- VISHNU Li, Xu, Song, paper in preparation

iEBE-VISHNU Initial conditions viscous hydro hadron cascade QGP HRG Various fluctuations in the hybrid model -Initial state fluctuations -Thermal fluctuations in viscous hydrodynamics -Thermal fluctuations during the switching between hydro & UrQMD (statistical hadronization, GCE;  Poisson fluctuations ) -fluctuations from UrQMD hadron cascade

Poisson fluctuations： Particle event generator: QGP hydro HRG UrQMD freeze-out/switching Various fluctuations in the hybrid model -Initial state fluctuations -Thermal fluctuations in viscous hydrodynamics -Thermal fluctuations during the switching between hydro & UrQMD (statistical hadronization, GCE;  Poisson fluctuations ) -fluctuations from UrQMD hadron cascade

Moments and Moment products of net-charges -For net charges, IEBE-VISHNU roughly describe the data of S and  and the related ratios, but shows certain deviations for 2/M (without charge conservation) Li, Xu, Song, paper in preparation

Cumulants and Moment Products of Net-protons -Small deviation from the Poisson baselines, roughly describe the data. -Lower collision energy, larger gap between data and model --charge conservation, critical fluct. First order phase transition

Multiplicity fluctuations of (net) Charges and (net) protons from iEBE- VISHNU Li, Xu, Song, paper in preparation -iEBE-VISHNU roughly describe most of the moments & moments products of (net) charges and (net) protons - What are dominant factors to influence the multiplicity fluct. -volume corrections ? -resonance decays ? -hadronic Scatterings ? … …

What is Volume Fluctuations /Corrections? Single hydro + many many UrQMD - Poisson fluctuations, no volume fluct/correc 2) In a certain centrality bins: Many (Single hydro + many many UrQMD) - many Poisson fluctuations are superimposed together --> volume fluct /correc & wide centrality bin effect 3) In a fine centrality bins: --> volume fluct /correc

Volume corrections, resonance decays & hadronic evolution -The effects of hadronic scatterings and resonance decays are very small -Volume corrections plays the dominant role for multiplicity fluctuations -For net protons, the effects of volume corrections are relatively small –>close to poisson fluctuations

Summary It is important to study both critical and non-critical fluctuations for BES and the search of the critical point Critical fluctuations near the QCD critical point -Static (equilibrium) critical fluctuation -qualitatively explain the acceptance dependence of critical fluctuations -C4 and 2 can be reproduced through tuning the parameters of the model -C2 , C3 are well above the poisson baselines, which can NOT describe the data -dynamical critical fluctuation -Sign of the C3, C4 cumulants can be different from the equilibrium one due to the memory effects -model A , model B, model H … Non-critical (thermal) Fluctuations -At higher collision energy, (net) charge distributions deviate from Poisson, (net) protons distributions are pretty close to Poisson -Volume correction is the main factors to influence the multiplicity fluct. Of (net) charges and (net) protons - It is possible to largely improve numerical efficiency, give better baseline

Initial State Fluctuations - Hydrodynamics and hybrid model has been fully developed -Lots of efforts from both exp and theory to study the initial state fluctuations and final state correlations -the QGP shear viscosity has been extracted with massive data evaluations! Critical Fluctuations -The study of dynamical critical fluctuations & full development of the dynamical model near the critical point are needed -We also need more realistic non-critical fluct baselines -where is the critical points located in the (T ) plane ? -what is the effective correlation length  ?

Thank You

Cumulants of Protons/Anti-protons -iEBE-VISHNU roughly describe the experimental data. -Small deviation from the Poisson baselines. Li, Xu, Song, paper in preparation

Moments of Positive/Negative Charges -iEBE-VISHNU model give a good description of M and  -For S and , the iEBE-VISHNU results shows cetrain deviations from the Poisson baseline. Li, Xu, Song, paper in preparation

Boltzmann approach with external field Stephanov PRD 2010 -analytical solution with perturbative expansion, please refer to Stephanov PRD 2010 Stationary solution for the Boltamann equation with external field Effective particle mass: