Presentation is loading. Please wait.

Presentation is loading. Please wait.

2009-4-291 Elliptic flow and incomplete equilibration in AMPT Jian-Li Liu Harbin Institute of Technology.

Published byMagdalene Ray Modified over 8 years ago

Similar presentations

Presentation on theme: "2009-4-291 Elliptic flow and incomplete equilibration in AMPT Jian-Li Liu Harbin Institute of Technology."— Presentation transcript:

1 2009-4-291 Elliptic flow and incomplete equilibration in AMPT Jian-Li Liu Harbin Institute of Technology

2 2009-4-292 Outline  Eccentricity scaled v 2 and incomplete equilibration  Variation of v 2 /εwith cross section  Variation of v 2 /εwith centrality  Summary

3 2009-4-293 Eccentricity scaled v 2 and incomplete equilibration Heiselberg & Levy, PRC59, 2716(1999) Collisionless limit: Ideal hydrodynamic limit: From collisionless limit to hydrodynamic limit: Bhalerao et al., PLB627, 49(2005) work well in 2-D transport model. Gombeaud & Ollitrault, PRC77, 054904(2008)

4 2009-4-294 Knudsen coefficient Time scale of formation of elliptic flow: Only longitudinal expansion: (dN/dy is constant) Bhalerao et al., PLB627, 49(2005)

5 2009-4-295 AMPT model data Differences: 1.c s is not constant from parton to hadron, BUT c s is approximately constant in parton stage 2. dN/dy is not constant. 3. 3-D expansion 4. Non-isotropic differential cross section. Molnar & Gyulassy, NPA697, 459(2002) Lin et al., PRC72, 064901(2005)

6 2009-4-296 Relation between isotropic cross section and anisotropic cross section For isotropic cross section: AMPT model: μis turned to fixed total cross section. Transport cross section is related to μ and s.

7 2009-4-297 Variation of v 2 /εwith cross section for quark Fitting parameters : Gombeaud et al. 2-D transport model (2008): Ideal hydrodynamics : Initial dN/dy : final s : initial dN/dy , final s : K 0 is sensitive to parameters used 27% 19% σ=3,6,10,14mb Issah et al., arXiv:nucl-ex/0604011

8 2009-4-298 HIJING hadron initial parton final parton hadron(c) hadron(f) Fitting parameters : 15% 11% ε , S is calculated for hadron from HIJING K 0 ( c ) is much larger than K 0 for quark: 1.Multiplicity difference 2. Variation of v 2 (c)/v 2 (quark) from 1.27 to 1.1 for cross section from 3mb to 14mb. 27% 19% Variation of v 2 /εwith cross section for hadron

9 2009-4-299 20% 14% Fitting parameters : HIJING hadron initial parton final parton hadron(c) hadron(f) 15% 11% Keeping dN/dy unchanged and replace V 2 (f) with V 2 (c): Deviation of elliptic flow from its hydrodynamic limit is almost the same as hadron(c). Keeping elliptic flow unchanged and Replace dN(f)/dy with dN(c)/dy: Deviation of elliptic flow from its hydrodynamic limit is almost unchanged. ε , S is calculated for hadron from HIJING Variation of v 2 /εwith cross section for hadron

10 2009-4-2910 Variation of v 2 /εwith centrality for quark

11 2009-4-2911 Changing the calculation of Knudsen coefficient

12 2009-4-2912 Changing the calculation of eccentricity Calculate eccentricity for quarks in all rapidity range. consistent with ideal hydrodynamic result

13 2009-4-2913 Only changing the calculation of eccentricity

14 2009-4-2914 1. Knudsen coefficient at initial stage : Possible reasons for changed calculation of Knudsen coefficient 2. “Effective” calculation of Knudsen coefficient defined by Bhalerao et al.: The transverse expansion of system maybe important and is related to the size of system.

15 2009-4-2915 Original calculation of Knudsen coefficient New calculation of Knudsen coefficient Dependence on cross section : 1.Relative distance between quark is related to cross section. 2.Quarks are coalesced according to their relative cross section Variation of v 2 /εwith centrality for hadron

16 2009-4-2916 Original calculation of Knudsen coefficient New calculation of Knudsen coefficient Dependence on cross section. Variation of v 2 /εwith centrality for hadron

17 2009-4-2917 Summary v 2 /εvariation with cross section for fixed parameter in AMPT model could be described well by the formula suggested Bhalerao et al. The deviation of v 2 /εof quark from its hydrodynamics limit is 19% ~ 27% for cross section from 6mb to 10mb. v 2 /εvariation with centrality for different cross section and collision energy in AMPT model could not be described by the formula suggested by Bhalerao et al, except the calculation of knudsen coefficient is changed.

18 2009-4-2918

Download ppt "2009-4-291 Elliptic flow and incomplete equilibration in AMPT Jian-Li Liu Harbin Institute of Technology."

Similar presentations

What do RHIC data tell us about thermalisation? J-Y Ollitrault Journée thématique IPN Orsay, 2 juin 2006.

What do RHIC data tell us about thermalisation? J-Y Ollitrault Journée thématique IPN Orsay, 2 juin 2006.
PID v2 and v4 from Au+Au Collisions at √sNN = 200 GeV at RHIC

PID v2 and v4 from Au+Au Collisions at √sNN = 200 GeV at RHIC
Zi-Wei Lin (ECU) 28th WWND, Puerto Rico April 10, 2012 1 Update of Initial Conditions in A Multiple Phase Transport (AMPT) Model Zi-Wei Lin Department.

Zi-Wei Lin (ECU) 28th WWND, Puerto Rico April 10, Update of Initial Conditions in A Multiple Phase Transport (AMPT) Model Zi-Wei Lin Department.
Elliptic flow of thermal photons in Au+Au collisions at 200GeV QNP2009 Beijing, Sep 21 - 26, 2009 F.M. Liu Central China Normal University, China T. Hirano.

Elliptic flow of thermal photons in Au+Au collisions at 200GeV QNP2009 Beijing, Sep , 2009 F.M. Liu Central China Normal University, China T. Hirano.
1 Transport and Hydrodynamic Model for Ultra-relativistic Heavy Ion Collisions Yu-Liang Yan China Institute of Atomic Energy Collaborators: Yun Cheng (CCNU,

1 Transport and Hydrodynamic Model for Ultra-relativistic Heavy Ion Collisions Yu-Liang Yan China Institute of Atomic Energy Collaborators: Yun Cheng (CCNU,
Anisotropic Flow at RHIC Jiayun Chen (for Collaboration) Institute of Particle Physics, HZNU, Wuhan, 430079, P.R.China Brookhaven National Lab, Upton,

Anisotropic Flow at RHIC Jiayun Chen (for Collaboration) Institute of Particle Physics, HZNU, Wuhan, , P.R.China Brookhaven National Lab, Upton,
First Alice Physics Week, Erice, Dec 4  9, 2005 1 Heavy  Flavor (c,b) Collectivity at RHIC and LHC Kai Schweda, University of Heidelberg A. Dainese,

First Alice Physics Week, Erice, Dec 4  9, Heavy  Flavor (c,b) Collectivity at RHIC and LHC Kai Schweda, University of Heidelberg A. Dainese,
Hadronic dissipative effects on transverse dynamics at RHIC Tetsufumi Hirano Dept. of Physics The Univ. of Tokyo QM2008, Feb. 4-10, 2008 TH, U.Heinz, D.Kharzeev,

Hadronic dissipative effects on transverse dynamics at RHIC Tetsufumi Hirano Dept. of Physics The Univ. of Tokyo QM2008, Feb. 4-10, 2008 TH, U.Heinz, D.Kharzeev,
Measurement of v 2 and v 4 in Au+Au Collisions at different beam energy from PHENIX Shengli Huang for PHENIX Collaboration Vanderbilt University.

Measurement of v 2 and v 4 in Au+Au Collisions at different beam energy from PHENIX Shengli Huang for PHENIX Collaboration Vanderbilt University.
1 Heavy Ion Collisions at LHC in a Multiphase Transport Model  A multi-phase transport (AMPT) model  Rapidity and transverse momentum distributions 

1 Heavy Ion Collisions at LHC in a Multiphase Transport Model  A multi-phase transport (AMPT) model  Rapidity and transverse momentum distributions 
Julia VelkovskaMoriond QCD, March 27, 2015 Geometry and Collective Behavior in Small Systems from PHENIX Julia Velkovska for the PHENIX Collaboration Moriond.

Julia VelkovskaMoriond QCD, March 27, 2015 Geometry and Collective Behavior in Small Systems from PHENIX Julia Velkovska for the PHENIX Collaboration Moriond.
Analysis of transverse momentum dependence of J/ψ in Heavy-Ion Collisions Xingbo Zhao with R. Rapp Cyclotron Institute + Physics Department Texas A&M University.

Analysis of transverse momentum dependence of J/ψ in Heavy-Ion Collisions Xingbo Zhao with R. Rapp Cyclotron Institute + Physics Department Texas A&M University.
Wolfgang Cassing CERN, 04.06.2007 Properties of the sQGP at RHIC and LHC energies.

Wolfgang Cassing CERN, Properties of the sQGP at RHIC and LHC energies.
1 Isotropization of an equilibrating Quark-Gluon Plasma Bin Zhang a, Lie-Wen Chen b, Che-Ming Ko c a Arkansas State University, b Shanghai Jiaotong University,

1 Isotropization of an equilibrating Quark-Gluon Plasma Bin Zhang a, Lie-Wen Chen b, Che-Ming Ko c a Arkansas State University, b Shanghai Jiaotong University,
Elliptic Flow and Constituent Quark Scaling

Elliptic Flow and Constituent Quark Scaling
System size and beam energy dependence of azimuthal anisotropy from PHENIX Michael Issah Vanderbilt University for the PHENIX Collaboration QM2008, Jaipur,

System size and beam energy dependence of azimuthal anisotropy from PHENIX Michael Issah Vanderbilt University for the PHENIX Collaboration QM2008, Jaipur,
Collective Flow Effects and Energy Loss in ultrarelativistic Heavy Ion Collisions Zhe Xu USTC, Hefei, July 11, 2008 with A. El, O. Fochler, C. Greiner.

Collective Flow Effects and Energy Loss in ultrarelativistic Heavy Ion Collisions Zhe Xu USTC, Hefei, July 11, 2008 with A. El, O. Fochler, C. Greiner.
Space time evolution of QCD matter Parton cascade with stochastic algorithm Transport rates and momentum isotropization Thermalization of gluons due to.

Space time evolution of QCD matter Parton cascade with stochastic algorithm Transport rates and momentum isotropization Thermalization of gluons due to.
1 Searching for the QGP at RHIC Che-Ming Ko Texas A&M University  Signatures of QGP  Quark coalescence Baryon/meson ratio Hadron elliptic flows and quark.

1 Searching for the QGP at RHIC Che-Ming Ko Texas A&M University  Signatures of QGP  Quark coalescence Baryon/meson ratio Hadron elliptic flows and quark.
The centrality dependence of elliptic flow Jean-Yves Ollitrault, Clément Gombeaud (Saclay), Hans-Joachim Drescher, Adrian Dumitru (Frankfurt) nucl-th/0702075.

The centrality dependence of elliptic flow Jean-Yves Ollitrault, Clément Gombeaud (Saclay), Hans-Joachim Drescher, Adrian Dumitru (Frankfurt) nucl-th/

Similar presentations

Ads by Google