Viscous Hydrodynamics for Relativistic Heavy-Ion Collisions: Riemann Solver for Quark-Gluon Plasma Kobayashi Maskawa Institute Department of Physics, Nagoya.

Slides:

Advertisements

Similar presentations

QGP Viscosity & Elliptic Flow for Multi-strange Hadrons

Advertisements

Dynamic Modeling for Relativistic Heavy Ion Collisions

New Results from Viscous Hydro + URQMD (VISHNU) International School for High Energy Nuclear Collisions, Wuhan, Oct 31- Nov.5, 2011 References: Supported.

Supported by DOE 11/22/2011 QGP viscosity at RHIC and LHC energies 1 Huichao Song 宋慧超 Seminar at the Interdisciplinary Center for Theoretical Study, USTC.

Rapidity Dependence of Transverse Momentum Correlations from Fluctuating Hydrodynamics Rajendra Pokharel 1, Sean Gavin 1 and George Moschelli 2 1 Wayne.

Duke University Chiho NONAKA in Collaboration with Masayuki Asakawa (Kyoto University) Hydrodynamical Evolution near the QCD Critical End Point June 26,

Effects of Bulk Viscosity on p T -Spectra and Elliptic Flow Parameter Akihiko Monnai Department of Physics, The University of Tokyo, Japan Collaborator:

Elliptic Flow Results From a Hybrid Model

Phase transition of hadronic matter in a non-equilibrium approach Graduate Days, Frankfurt, , Hannah Petersen, Universität Frankfurt.

First Results From a Hydro + Boltzmann Hybrid Approach DPG-Tagung, Darmstadt, , Hannah Petersen, Universität Frankfurt.

Freeze-Out in a Hybrid Model Freeze-out Workshop, Goethe-Universität Frankfurt Hannah Petersen.

The QCD Phase Diagram in Relativistic Heavy Ion Collisions October 24, Inauguration Conference Chiho NONAKA, Nagoya University.

Marcus Bleicher, WWND 2008 A fully integrated (3+1) dimensional Hydro + Boltzmann Hybrid Approach Marcus Bleicher Institut für Theoretische Physik Goethe.

Space time evolution of QCD matter Parton cascade with stochastic algorithm Transport rates and momentum isotropization Thermalization of gluons due to.

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

Perfect Fluid: flow measurements are described by ideal hydro Problem: all fluids have some viscosity -- can we measure it? I. Radial flow fluctuations:

Perfect Fluid: flow measurements are described by ideal hydro Problem: all fluids have some viscosity -- can we measure it? I. Transverse flow fluctuations:

Effects of Bulk Viscosity at Freezeout Akihiko Monnai Department of Physics, The University of Tokyo Collaborator: Tetsufumi Hirano Nagoya Mini-Workshop.

Viscous hydrodynamics DPF 2009 Huichao Song The Ohio State University Supported by DOE 07/30/2009 July 27-July 31, Detroit, MI with shear and bulk viscosity.

Viscous hydrodynamics and the QCD equation of state Azwinndini Muronga 1,2 1 Centre for Theoretical Physics and Astrophysics Department of Physics, University.

Viscous hydrodynamics and Transport Models Azwinndini Muronga 1,2 1 Centre for Theoretical Physics and Astrophysics Department of Physics, University of.

Sept WPCF-2008 Initial conditions and space-time scales in relativistic heavy ion collisions Yu. Sinyukov, BITP, Kiev Based on: Yu.S., I. Karpenko,

Nonequilibrium Dynamics in Astrophysics and Material Science YITP, Kyoto, Japan, Oct. 31-Nov. 3, 2011 Tetsufumi Hirano Sophia Univ./the Univ. of Tokyo.

Hydrodynamic Tests of Fluctuating Initial Conditions George Moschelli & Hannu Holopainen Transport Meeting 24 January 2012.

相対論的流体模型を軸にした重イオン衝突の理解

Perfect Fluid: flow measurements are described by ideal hydro Problem: all fluids have some viscosity -- can we measure it? I. Radial flow fluctuations:

Flow fluctuation and event plane correlation from E-by-E Hydrodynamics and Transport Model LongGang Pang 1, Victor Roy 1,, Guang-You Qin 1, & Xin-Nian.

AMS 691 Special Topics in Applied Mathematics Lecture 3 James Glimm Department of Applied Mathematics and Statistics, Stony Brook University Brookhaven.

The effects of viscosity on hydrodynamical evolution of QGP 苏中乾大连理工大学 Dalian University of Technology.

Akihiko Monnai Department of Physics, The University of Tokyo Collaborator: Tetsufumi Hirano Viscous Hydrodynamics for Relativistic Systems with Multi-Components.

Workshop for Particle Correlations and Femtoscopy 2011

Jaipur February 2008 Quark Matter 2008 Initial conditions and space-time scales in relativistic heavy ion collisions Yu. Sinyukov, BITP, Kiev (with participation.

Heavy Ion Meeting, Yonsei University Seoul, Dec. 10, 2011 T.H., P.Huovinen, K.Murase, Y.Nara (in preparation)

Akihiko Monnai Department of Physics, The University of Tokyo Collaborator: Tetsufumi Hirano Viscous Hydrodynamics Heavy Ion Meeting December 10.

Flow in heavy ion collisions Urs Achim Wiedemann CERN PH-TH Latsis-Symposium, 5 June 2013, Zurich.

Akihiko Monnai Department of Physics, The University of Tokyo Collaborator: Tetsufumi Hirano V iscous Hydrodynamic Expansion of the Quark- Gluon Plasma.

Viscous hydrodynamics Quark Matter 2009 Huichao Song and Ulrich Heinz The Ohio State University Supported by DOE 04/02/2009 March 30-April 4, Knoxville,

QM2012, Washington, DC, Aug. 13-Aug. 18, 2012 Supported by DOE 08/13/2012 QGP viscosity at RHIC and LHC energies Huichao Song Thanks for discussions with.

The quest for the holy Grail: from Glasma to Plasma Raju Venugopalan CATHIE-TECHQM workshop, Dec , 2009 Color Glass Condensates Initial Singularity.

Flow fluctuation and event plane correlation from E-by-E Hydrodynamics and Transport Model Victor Roy Central China Normal University, Wuhan, China Collaborators.

Koichi Murase A, Tetsufumi Hirano B The University of Tokyo A, Sophia University B Hydrodynamic fluctuations and dissipation in an integrated dynamical.

Does HBT interferometry probe thermalization? Clément Gombeaud, Tuomas Lappi and J-Y Ollitrault IPhT Saclay WPCF 2009, CERN, October 16, 2009.

Partial thermalization, a key ingredient of the HBT Puzzle Clément Gombeaud CEA/Saclay-CNRS Quark-Matter 09, April 09.

Akihiko Monnai Department of Physics, The University of Tokyo Collaborator: Tetsufumi Hirano Relativistic Viscous Hydrodynamics for Multi-Component Systems.

Scaling of Elliptic Flow for a fluid at Finite Shear Viscosity V. Greco M. Colonna M. Di Toro G. Ferini From the Coulomb Barrier to the Quark-Gluon Plasma,

Elliptic flow and shear viscosity in a parton cascade approach G. Ferini INFN-LNS, Catania P. Castorina, M. Colonna, M. Di Toro, V. Greco.

Fluctuating hydrodynamics confronts rapidity dependence of p T -correlations Rajendra Pokharel 1, Sean Gavin 1 and George Moschelli 2 1 Wayne State University.

Akihiko Monnai Department of Physics, The University of Tokyo Collaborator: Tetsufumi Hirano C ausal Viscous Hydrodynamics for Relativistic Systems with.

Results from an Integrated Boltzmann+Hydrodynamics Approach WPCF 2008, Krakau, Jan Steinheimer-Froschauer, Universität Frankfurt.

Heavy-Ion Physics - Hydrodynamic Approach Introduction Hydrodynamic aspect Observables explained Recombination model Summary 전남대 이강석 HIM

Relativistic Theory of Hydrodynamic Fluctuations Joe Kapusta University of Minnesota Nuclear Physics Seminar October 21, 2011 Collaborators: Berndt Muller.

R. Lednicky: Joint Institute for Nuclear Research, Dubna, Russia I.P. Lokhtin, A.M. Snigirev, L.V. Malinina: Moscow State University, Institute of Nuclear.

Hydrodynamic Flow from Fast Particles Jorge Casalderrey-Solana. E. V. Shuryak, D. Teaney SUNY- Stony Brook.

PhD student at the International PhD Studies Institute of Nuclear Physics PAN Institute of Nuclear Physics PAN Department of Theory of Structure of Matter.

Hydrodynamic Analysis of Relativistic Heavy Ion Collisions at RHIC and LHC Tetsufumi Hirano The Univ. of Tokyo & LBNL Collaborators: Pasi Huovinen and.

Heavy quark energy loss in hot and dense nuclear matter Shanshan Cao In Collaboration with G.Y. Qin, S.A. Bass and B. Mueller Duke University.

Flow and Dissipation in Ultrarelativistic Heavy Ion Collisions September 16 th 2009, ECT* Italy Akihiko Monnai Department of Physics, The University of.

3 rd Joint Meeting of the Nuclear Physics Divisions of the APS and the JPS October 15 th 2009, Hawaii USA Akihiko Monnai Department of Physics, The University.

Koichi Murase, The University of Tokyo, Sophia University Relativistic fluctuating hydrodynamics 2016/2/18, ATHIC 2016, New Delhi, India 2016/2/181.

Shear Viscosity and Collective Flow in Heavy Ion Collisions within Parton Cascade Calculations Zhe Xu, Carsten Greiner Trento, Sept. 17, 2009 Institut.

Comparisons between hydrodynamics and transport calculations Zhe Xu WPCF, Krakow, Sept. 11, 2008.

Radiative transport: comparisons between BAMPS and viscous hydro Zhe Xu with I.Bouras, A.El, O.Fochler, F.Lauciello, E.Molnar, H.Niemi, C.Greiner, D.H..Rischke.

Soft physics in PbPb at the LHC Hadron Collider Physics 2011 P. Kuijer ALICECMSATLAS Necessarily incomplete.

Dynamical modeling of the chiral magnetic effect in heavy-ion collisions [arXiv: ] Yuji Hirono [Stony Brook Univ.] Collaborators: T. Hirano[Sophia.

Akihiko Monnai Department of Physics, The University of Tokyo Collaborator: Tetsufumi Hirano V iscous Hydrodynamic Evolution with Non-Boost Invariant Flow.

Duke University 野中千穂 Hadron production in heavy ion collision: Fragmentation and recombination in Collaboration with R. J. Fries (Duke), B. Muller (Duke),

Chiho Nonaka QM2009 Nagoya University Chiho NONAKA March 31, Matter 2009, Knoxville, TN In collaboration with Asakawa, Bass, and Mueller.

Hydro + Cascade Model at RHIC

Recent Development in RELATIVISTIC HYDRODYNAMIC MODEL

Effects of Bulk Viscosity on pT Spectra and Elliptic Flow Coefficients

Presentation transcript:

Viscous Hydrodynamics for Relativistic Heavy-Ion Collisions: Riemann Solver for Quark-Gluon Plasma Kobayashi Maskawa Institute Department of Physics, Nagoya University Chiho NONAKA December 5, 2013, YITP, Kyoto Hydrodynamic Model: Yukinao Akamatsu, Shu-ichiro Inutsuka, Makoto Takamoto Hybrid Model: Yukinao Akamatsu, Steffen Bass, Jonah Bernhard

C. NONAKA Numerical Algorithm Current understanding thermalization hydrohadronizationfreezeout collisions hydrodynamic model hadron based event generator fluctuating initial conditions

C. NONAKA Numerical Algorithm Current understanding thermalization hydrohadronizationfreezeout collisions hydrodynamic model hadron based event generator fluctuating initial conditions Initial geometry fluctuations MC-Glauber, MC-KLN, MC-rcBK, IP-Glasma… vnvn Hydrodynamic expansion

C. NONAKA Ollitrault

C. NONAKA Ollitrault Event-by-event calculation!

C. NONAKA Ollitrault Event-by-event calculation! small structure Shock-wave capturing scheme Stable, less numerical viscosity

C. NONAKA Numerical Algorithm Current understanding thermalization hydrohadronizationfreezeout collisions hydrodynamic model hadron based event generator fluctuating initial conditions Initial geometry fluctuations MC-Glauber, MC-KLN, MC-rcBK, IP-Glasma… vnvn Hydrodynamic expansion numerical method

C. NONAKA HYDRODYNAMIC MODEL Akamatsu, Inutsuka, CN, Takamoto: arXiv: 、 J. Comp. Phys. (2014) 34

C. NONAKA Viscous Hydrodynamic Model Relativistic viscous hydrodynamic equation – First order in gradient: acausality – Second order in gradient: Israel-Stewart, Ottinger and Grmela, AdS/CFT, Grad’s 14-momentum expansion, Renomarization group Numerical scheme – Shock-wave capturing schemes: Riemann problem Godunov scheme: analytical solution of Riemann problem SHASTA: the first version of Flux Corrected Transport algorithm, Song, Heinz, Pang, Victor… Kurganov-Tadmor (KT) scheme, McGill

C. NONAKA Our Approach Israel-Stewart Theory Takamoto and Inutsuka, arXiv: dissipative fluid dynamics = advection + dissipation 2. relaxation equation = advection + stiff equation Riemann solver: Godunov method (ideal hydro) Mignone, Plewa and Bodo, Astrophys. J. S160, 199 (2005) Two shock approximation exact solution Rarefaction wave Shock wave Contact discontinuity Rarefaction wave shock wave Akamatsu, Inutsuka, CN, Takamoto, arXiv:

C. NONAKA Relaxation Equation Numerical scheme + advection stiff equation up wind method Piecewise exact solution ~constant during  t Takamoto and Inutsuka, arXiv: fast numerical scheme

C. NONAKA Comparison Shock Tube Test : Molnar, Niemi, Rischke, Eur.Phys.J.C65,615(2010) T L =0.4 GeV v=0 T R =0.2 GeV v= Nx=100, dx=0.1, dt=0.04 Analytical solution Numerical schemes SHASTA, KT, NT Our scheme EoS: ideal gas

C. NONAKA Shocktube problem Ideal case shockwave rarefaction

C. NONAKA L1 Norm Numerical dissipation: deviation from analytical solution N cell =100: dx=0.1 fm =10 fm For analysis of heavy ion collisions T L =0.4 GeV v=0 T R =0.2 GeV v=0 0 10

C. NONAKA Large  T difference T L =0.4 GeV, T R =0.172 GeV – SHASTA becomes unstable. – Our algorithm is stable. SHASTA: anti diffusion term, A ad – A ad = 1 : default value, unstable – A ad =0.99: stable, more numerical dissipation T L =0.4 GeV v=0 T R =0.172 GeV v= Nx=100, dx=0.1, dt=0.04 EoS: ideal gas

C. NONAKA L1 norm SHASTA with small A ad has large numerical dissipation Aad=1 Aad=0.99 T L =400, T R =200 T L =400, T R =172 =10 fm

C. NONAKA Artificial and Physical Viscosities Molnar, Niemi, Rischke, Eur.Phys.J.C65,615(2010) Antidiffusion terms : artificial viscosity stability

C. NONAKA Large  T difference T L =0.4 GeV, T R =0.172 GeV – SHASTA becomes unstable. – Our algorithm is stable. SHASTA: anti diffusion term, A ad – A ad = 1 : default value – A ad =0.99: stable, more numerical dissipation Large fluctuation (ex initial conditions) – Our algorithm is stable even with small numerical dissipation. T L =0.4 GeV v=0 T R =0.172 GeV v= Nx=100, dx=0.1, dt=0.04 EoS: ideal gas

C. NONAKA HYBRID MODEL

C. NONAKA Our Hybrid Model thermalization hydrohadronizationfreezeout collisions hydrodynamic model MC-KLN Nara UrQMD CorneliusOscar sampler Freezeout hypersurface finder Huovinen, PetersenOhio group Fluctuating Initial conditionsHydrodynamic expansionFreezeout process From Hydro to particle Final state interactions Akamatsu, Inutsuka, CN, Takamoto, arXiv: 、 J. Comp. Phys. (2014) 34

C. NONAKA Our Hybrid Model thermalization hydrohadronizationfreezeout collisions hydrodynamic model MC-KLN Nara UrQMD CorneliusOscar sampler Freezeout hypersurface finder Huovinen, PetersenOhio group Fluctuating Initial conditionsHydrodynamic expansionFreezeout process From Hydro to particle Final state interactions Akamatsu, Inutsuka, CN, Takamoto, arXiv: 、 J. Comp. Phys. (2014) 34 Simulation setups: Free gluon EoS Hydro in 2D boost invariant simulation UrQMD with |y|<0.5

C. NONAKA Initial Pressure Distribution MC-KLN (centrality 15-20%) LHC RHIC Pressure (fm -4 ) X(fm) Y(fm)

C. NONAKA Time Evolution of Entropy Entropy of hydro (T>T SW =155MeV)

C. NONAKA Time Evolution of  n and v n Eccentricity & Flow anisotropy Shift the origin so that ε 1 =0

C. NONAKA Eccentricities vs higher harmonics LHC (200 events) nn vnvn

C. NONAKA Eccentricities vs higher harmonics RHIC (200 events) nn vnvn

C. NONAKA Hydro + UrQMD Transverse momentum spectrum LHCRHIC

C. NONAKA Effect of Hadronic Interaction Transverse momentum distribution LHCRHIC

C. NONAKA Higher harmonics from Hydro + UrQMD Effect of hadronic interaction

C. NONAKA Summary We develop a state-of-the-art numerical scheme – Viscosity effect – Shock wave capturing scheme: Godunov method – Less artificial diffusion: crucial for viscosity analyses – Stable for strong shock wave Construction of a hybrid model – Fluctuating initial conditions + Hydrodynamic evolution + UrQMD Higher Harmonics – Time evolution, hadron interaction Our algorithm Importance of numerical scheme