The puzzling relation between the RAA and the v2 for heavy mesons in a Boltzmann and in a Langevin approach F. Scardina, S.K. Das, S. Plumari, V.Greco.

Slides:



Advertisements
Similar presentations
Recombination for JET Shower MC: Status and Discussion Rainer Fries Texas A&M University JET NLO & MC Meeting Wayne State University, August 23, 2013 On.
Advertisements

Heavy Flavor Dynamics in Relativistic Heavy-ion Collisions Shanshan Cao Duke University In collaboration with Guang-You Qin and Steffen A. Bass Huada School.
Fukutaro Kajihara (CNS, University of Tokyo) for the PHENIX Collaboration Heavy Quark Measurements by Weak-Decayed Electrons at RHIC-PHENIX.
F. Scardina INFN-LNS Catania, University of Messina V. Greco, M. Di Toro Sensitivity of the jet quenching observables to the temperature dependence of.
1 Heavy Ion Collisions at LHC in a Multiphase Transport Model  A multi-phase transport (AMPT) model  Rapidity and transverse momentum distributions 
Forward-Backward Correlations in Relativistic Heavy Ion Collisions Aaron Swindell, Morehouse College REU 2006: Cyclotron Institute, Texas A&M University.
24th Winter Workshop Nuclear Dynamics 1 Towards an understanding of the single electron spectra or what can we learn from heavy quarks of a plasma? P.-B.
Wolfgang Cassing CERN, Properties of the sQGP at RHIC and LHC energies.
Luan Cheng (Institute of Particle Physics, Huazhong Normal University) I. Introduction II. Interaction Potential with Flow III. Flow Effects on Light Quark.
1  /e + e - arXiv: [nucl.th]. 2 3 Sometime ago it was noted that: “The ratio of the production rates (  /  +  - ) and (  o,  /  +  -
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.
F. Scardina INFN-LNS Catania, University of Messina V. Greco, M. Di Toro Jet quenching Dynamics [Based on arXiv: (today) ]
M. Djordjevic 1 Effect of dynamical QCD medium on radiative heavy quark energy loss Magdalena Djordjevic The Ohio State University.
M. Djordjevic 1 Heavy quark energy loss in a dynamical QCD medium Magdalena Djordjevic The Ohio State University M. Djordjevic and U. Heinz, arXiv:
University of Catania INFN-LNS Heavy flavor Suppression : Langevin vs Boltzmann S. K. Das, F. Scardina V. Greco, S. Plumari.
F. Scardina University of Catania INFN-LNS Heavy Flavor in Medium Momentum Evolution: Langevin vs Boltzmann V. Greco S. K. Das S. Plumari V. Minissale.
Heavy Flavor Evolution in QGP and Hadron Gas: Suppression, Flow and Angular De-correlation Shanshan Cao Duke University In collaboration with Guang-You.
Guang-You Qin and Steffen A. Bass
Jet energy loss at RHIC and LHC including collisional and radiative and geometric fluctuations Simon Wicks, QM2006 Work done with Miklos Gyulassy, William.
Flow fluctuation and event plane correlation from E-by-E Hydrodynamics and Transport Model Victor Roy Central China Normal University, Wuhan, China Collaborators.
M. Djordjevic 1 Theoretical predictions of jet suppression: a systematic comparison with RHIC and LHC data Magdalena Djordjevic Institute of Physics Belgrade,
Heavy Quark Dynamics in the QGP: Boltzmann vs Langevin V. Greco Santosh Kumar Das Francesco Scardina.
Transport Theory of Open Heavy Flavor in Heavy-Ion Collisions Shanshan Cao Lawrence Berkeley National Lab In collaboration with G.-Y. Qin, and S. Bass.
Round Table Workshop on NICA Physics Dubna,September 9-12,20091 J/Ψ Production in Heavy Ion Collisions J/Ψ Production in Heavy Ion Collisions Pengfei ZHUANG.
Workshop on QCD and RHIC Physics, Hefei, July Heavy Flavors in High Energy Nuclear Collisions ZHUANG Pengfei (Tsinghua University, Beijing) ● J/Psi.
Ralf Rapp Cyclotron Institute + Physics Department Texas A&M University College Station, USA International Conference on Strangeness in Quark Matter 2008.
1 Transport description of viscous effects Che-Ming Ko Texas A&M University  Introduction  A multi-phase transport (AMPT) model  Anisotropic flow -
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.
Probing QGP by Heavy Flavors Santosh Kumar Das Theoretical Physics Division.
Yukinao Akamatsu Univ. of Tokyo 2008/11/26 Komaba Seminar Ref : Y. A., T. Hatsuda and T. Hirano, arXiv: [hep-ph] 1.
Charm elliptic flow at RHIC B. Zhang 1, L.W. Chen 2, C.M. Ko 3 1 Arkansas State University, 2 Shanghai Jiao Tong University, 3 Texas A&M University Charm.
F. Scardina University of Catania INFN-LNS Heavy Flavor in Medium Momentum Evolution: Langevin vs Boltzmann V. Greco S. K. Das S. Plumari The 30 th Winter.
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.
M. Djordjevic 1 Heavy flavor suppression in a dynamical medium with finite magnetic mass Magdalena Djordjevic Institute of Physics Belgrade, University.
M. Djordjevic 1 Heavy quark energy loss in a dynamical QCD medium Magdalena Djordjevic The Ohio State University M. Djordjevic and U. Heinz, arXiv:
M. Djordjevic 1 Suppression and energy loss in Quark-Gluon Plasma Magdalena Djordjevic Institute of Physics Belgrade, University of Belgrade.
Parton showers as a source of energy-momentum deposition and the implications for jet observables Bryon Neufeld, LANL 1Neufeld Based on the preprint R.B.
Shear Viscosity and Collective Flow in Heavy Ion Collisions within Parton Cascade Calculations Zhe Xu, Carsten Greiner Trento, Sept. 17, 2009 Institut.
Collectivity in a Parton Cascade Zhe Xu BNL, April 30, 2008 with A. El, O. Fochler, C. Greiner and H. Stöcker.
Production, energy loss and elliptic flow of heavy quarks at RHIC and LHC Jan Uphoff with O. Fochler, Z. Xu and C. Greiner Hard Probes 2010, Eilat October.
From microscopic interactions to the dynamics of the fireball in collaboration with: I.Bouras, A. El, O. Fochler, M. Greif, F. Reining, F. Senzel, J. Uphoff,
Heavy Quark Dynamics in the QGP: Boltzmann vs Langevin V. Greco Santosh Kumar Das Francesco Scardina 52 nd International Winter Meeting on Nuclear Physics.
Heavy quarks and charmonium at RHIC and LHC within a partonic transport model Jan Uphoff with O. Fochler, Z. Xu and C. Greiner XLIX International Winter.
Heavy-Quark Thermalization and Resonances in the QGP Ralf Rapp Cyclotron Institute + Physics Department Texas A&M University College Station, USA With:
Lawrence Berkeley National Laboratory
SQM,UC Berkeley 27 June- 1July 2016
Review of ALICE Experiments
Probing QGP-medium interactions
Sedat Altınpınar for the ALICE Collaboration
Heavy-Flavor Transport at FAIR
Heavy-flavor particle correlations - From RHIC to LHC
Yukinao Akamatsu 赤松 幸尚 (Univ. of Tokyo)
Open charm production in pp and Pb-Pb collisions in ALICE at the LHC
Hadro Chemistry with High-PT Particles in Nuclear Collisions
for the ALICE collaboration University of Tennessee at Knoxville
Yukinao Akamatsu Tetsuo Hatsuda Tetsufumi Hirano (Univ. of Tokyo)
Johann Wolfgang Goethe-Universität Frankfurt
QCD (Quantum ChromoDynamics)
STAR and RHIC; past, present and future.
Heavy-Flavour Physics in Heavy-Ion Collisions
Fragmentation and Recombination for Exotics in Heavy Ion Collisions
Heavy Quark and charm propagation in Quark-Gluon plasma
Modification of Fragmentation Function in Strong Interacting Medium
Charmed hadron signals of partonic medium
What can we learn about QGP from heavy flavour probes?
Shingo Sakai for PHENIX Collaborations (Univ. of Tsukuba)
GLOBAL POLARIZATION OF QUARKS IN NON-CENTRAL A+A COLLISIONS
QGP Formation Signals and Quark Recombination Model
Presentation transcript:

The puzzling relation between the RAA and the v2 for heavy mesons in a Boltzmann and in a Langevin approach F. Scardina, S.K. Das, S. Plumari, V.Greco University of Catania, INFN-LNS Two different approaches for the Propagation of Heavy quark in the QGP The heavy quarks (HQ), Charm and bottom, are ideal probes to study the Quark Gluon Plasma (QGP). HQ are considered heavy for a two-fold reason: first, typical of particles physics, is that the mass is much larger than QCD which make possible the evaluation of the cross section and momentum spectra within the next to lead order; the second more inherent to plasma physics is that their masses are much larger than the temperature and therefore they may expect to decouple from the medium and moreover their thermal production in the QGP is expected to be negligible. Therefore they are produced mainly in the initial hard parton scatterings of nucleon-nucleon interactions being witness of the entire-space time evolution of the system and can reveal important information about the properties of QGP. Both at RHIC and LHC energies it has been observed a puzzling correlation between the nuclear suppression factor RAA and the elliptic flow v2 that has challenged all the existing models. The propagation of heavy quarks through the quark-gluon plasma (QGP) has been quite often treated within the framework of Langevin equation (LV), i.e. assuming the heavy flavor momentum transfer is small or the scatterings are sufficiently forward peaked. We address a direct comparison between the Langevin dynamics and the Boltzmann collisional integral (BM). Transport approach Fokker Planck approach Describes the evolution of the one body distribution function f(x,p) of the bulk and also of Heavy Quarks Boltzmann equation (B-E) The Fokker Planck equation can be derived from the Boltzmann equation expanding the collision integral in terms of the transferred momentum k making the assumption that k is << than the momentum p of the HQ. Fokker Planck equation Drag and Diffusion Coefficients Collision Integral The Fokker-Planck equation is equivalent to an ordinary stochastic differential equation : The Langevin equation (L-E) Transition rate for collisions of Heavy quarks with heath bath changing the HQ momentum from p to p-k is the deterministic friction (drag) force Cij is a stochastic force in terms of independent Gaussian-normal distributed random variable ρ=(ρx,ρy,ρz) To solve numerically the B-E we divide the space into a 3-D lattice and we use the standard test particle method to sample f(x,p). C22 is solved using a stochastic algorithm consisting into the evaluation of the collision probability P22 for each couple of particle in the cells. The covariance matrix and  are related to the diffusion matrix and to the drag coefficient by [H. van Hees, V. Greco and R. Rapp, Phys. Rev. C73, 034913 (2006) ],[G. D. Moore, D Teaney, Phys. Rev. C 71, 064904(2005)] [S. Cao, S. A. Bass Phys. Rev. C 84, 064902 (2011) ], [Majumda, T. Bhattacharyya, J. Alam and S. K. Das, Phys. Rev. C,84, 044901(2012)] [T. Lang, H. van Hees, J. Steinheimer and M. Bleicher arXiv:1208.1643 [hep-ph]],[C. Young , B. Schenke , S. Jeon and C. Gale PRC 86, 034905 (2012)] [S. K. Das , F. Scardina, V. Greco arXiV:1312.6857],[J. Uphoff, O. Fochler, Z. Xu and C. Greiner PRC 84 024908; PLB 717] [B. Zhang, L. W. Chen and C. M. Ko, Phys. Rev. C 72 (2005) 024906][P. B. Gossiaux, J. B. Aichelin PRC 78 014904] [D. Molnar, Eur. Phys. J. C 49(2007) 181] pQCD evaluation of , Ai and Bij Simulations in a static medium Simulations in which a particle ensemble in a box evolves dynamically Bulk composed only by gluons in thermal equilibrium at T=400 MeV Heavy Quarks are distributed uniformly in coordinate space LV/BM Mass dependence of the LV/BM To analyze the comparison between the Fokker-Planck approach and the Boltzmann approach we have studied the ratio between the spectra coming from the simulations with LV and the spectra coming from the BM. In order to study the mass dependence of the approximation involved in the LV we have compared such a ratio for both charm (Mc=1.3 GeV) and Bottom (Mb=4.2 GeV). Moreover we have compared LV and BM simulating different values of the average momentum transferred k (different values of the Debye screening mass mD.) Average momentum transfer (<k>) dependence of the LV/BM [S. K. Das , F. Scardina, V. Greco arXiV:1312.6857] Realistic simulation of HIC RHIC LHC RAA(pT) V2(pT) The Langevin dynamics overestimates the interaction for charms (large suppression) while in case of bottom quarks the approximation appears to be quite reasonable However one can gets very similar RAA for both the approaches just reducing the diffusion coefficient Boltzmann is more efficient in producing v2 for fixed RAA especially for large average momentum transfer This together with a coalescence hadronization mechanism may quenches the puzzling RAA and v2 observations