M. Djordjevic 1 Heavy flavor suppression in a dynamical medium with finite magnetic mass Magdalena Djordjevic Institute of Physics Belgrade, University.

Slides:



Advertisements
Similar presentations
Charm & bottom RHIC Shingo Sakai Univ. of California, Los Angeles 1.
Advertisements

1Erice 2012, Roy A. Lacey, Stony Brook University.
Collisional energy loss in a finite size QCD medium revisited Alejandro Ayala Instituto de Ciencias Nucleares, UNAM.
M. Djordjevic 1 Open questions in heavy flavor physics at RHIC Magdalena Djordjevic The Ohio State University.
Relativistic Heavy-Ion Collisions: Recent Results from RHIC David Hardtke LBNL.
M. Djordjevic 1 Heavy quark energy loss puzzle at RHIC Magdalena Djordjevic The Ohio State University.
Quark recombination in high energy collisions for different energies Steven Rose Worcester Polytechnic Institute Mentor: Dr. Rainer Fries Texas A&M University.
We distinguish two hadronization mechanisms:  Fragmentation Fragmentation builds on the idea of a single quark in the vacuum, it doesn’t consider many.
#: 1... and your jet energy loss calculation? What drives you? aka Perturbative jet energy loss mechanisms: Learning from RHIC, extrapolating to LHC Simon.
Luan Cheng (Institute of Particle Physics, Huazhong Normal University) I. Introduction II. Interaction Potential with Flow III. Flow Effects on Light Quark.
1 Heavy Quark Energy Loss Tatia Engelmore Journal Club 7/21.
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:
Heavy-to-light ratios as a test of medium-induced energy loss at RHIC and the LHC N. Armesto Quark Matter 2005: 18th International Conference on Ultra-Relativistic.
Anomaly of over ratios in Au+Au collision with jet quenching Xiaofang Chen IOPP, CCNU Collaborator: Enke Wang Hanzhong Zhang Benwei Zhang Beijing Mar.
Precision Probes for Hot QCD Matter Rainer Fries Texas A&M University & RIKEN BNL QCD Workshop, Washington DC December 15, 2006.
1 Search for the Effects of the QCD Color Factor in High-Energy Collisions at RHIC Bedanga Mohanty LBNL  Motivation  Color Factors  Search for Color.
Luan Cheng (Institute of Particle Physics, Huazhong Normal University) I.Introduction II. Potential Model with Flow III.Flow Effects on Parton Energy Loss.
Jet energy loss at RHIC and LHC including collisional and radiative and geometric fluctuations Simon Wicks, QM2006 Work done with Miklos Gyulassy, William.
09/15/10Waye State University1 Elliptic Flow of Inclusive Photon Ahmed M. Hamed Midwest Critical Mass University of Toledo, Ohio October, 2005 Wayne.
High Pt physics with TOF ALICE B.V.Zagreev ITEP
Jet Physics in ALICE Mercedes López Noriega - CERN for the ALICE Collaboration Hot Quarks 2006 Villasimius, Sardinia - Italy.
M. Djordjevic 1 Theoretical predictions of jet suppression: a systematic comparison with RHIC and LHC data Magdalena Djordjevic Institute of Physics Belgrade,
Simon Wicks Columbia University Work done with William Horowitz, Magdalena Djordjevic and Miklos Gyulassy with input from Azfar Adil BNL Heavy Flavor Workshop,
1 Fukutaro Kajihara (CNS, University of Tokyo) for the PHENIX Collaboration Heavy Quark Measurement by Single Electrons in the PHENIX Experiment.
Radiative heavy quark energy loss in QCD matter Magdalena Djordjevic and Miklos Gyulassy Columbia University.
Study of b quark contributions to non-photonic electron yields by azimuthal angular correlations between non-photonic electrons and hadrons Shingo Sakai.
Heavy Quark Energy Loss due to Three-body Scattering in a Quark- Gluon Plasma Wei Liu Texas A&M University  Introduction  Heavy quark scattering in QGP.
Heavy-Ion Physics - Hydrodynamic Approach Introduction Hydrodynamic aspect Observables explained Recombination model Summary 전남대 이강석 HIM
D.Arkhipkin, Y. Zoulkarneeva, Workshop of European Research Group on Ultra relativistic Heavy Ion Physics March 9 th 2006 Transverse momentum and centrality.
News from ALICE Jan PLUTA Heavy Ion Reaction Group (HIRG) Warsaw University of Technology February 22, XIII GDRE Workshop, SUBATECH, Nantes.
Elliptic flow of electrons from heavy flavor decays
Results from ALICE Christine Nattrass for the ALICE collaboration University of Tennessee at Knoxville.
Heavy Quark Energy Loss with Twist Expansion Approach Ben-Wei Zhang Institute of Particle Physics Central China Normal Univeristy CCAST, Beijing --- Augest.
Elastic, Inelastic and Path Length Fluctuations in Jet Tomography Simon Wicks Hard Probes 2006 Work done with William Horowitz, Magdalena Djordjevic and.
Squaw Valley, Feb. 2013, Roy A. Lacey, Stony Brook University Take home message  The scaling (p T, ε, R, ∆L, etc) properties of azimuthal anisotropy.
Enke Wang (Institute of Particle Physics, Huazhong Normal University) I. Introduction II. Ineraction Potential with Flow III.Flow Effects on Light Quark.
QM04 1/12/04M. Djordjevic 1 Heavy quark energy loss-Applications to RHIC Magdalena Djordjevic and Miklos Gyulassy Columbia University The Ter-Mikayelian.
Collisional energy loss becomes probable André Peshier SUBATECH, Université de Nantes - Praha, 20 April
M. Djordjevic 1 Heavy Quark Energy Loss in Nucleus-Nucleus Collisions Magdalena Djordjevic The Ohio State University.
Elliptic flow of electron from heavy flavor decay by the PHENIX Shingo Sakai for PHENIX collaboration (Univ. of Tsukuba & JPSP)
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 quark energy loss in a dynamical QCD medium Magdalena Djordjevic The Ohio State University M. Djordjevic and U. Heinz, arXiv:
M. Djordjevic 1 Hard probes at RHIC and LHC Magdalena Djordjevic Ohio State University.
M. Djordjevic 1 Light and heavy flavor phenomenology at RHIC and LHC Magdalena Djordjevic Institute of Physics Belgrade, University of Belgrade.
M. Djordjevic 1 Suppression and energy loss in Quark-Gluon Plasma Magdalena Djordjevic Institute of Physics Belgrade, University of Belgrade.
SPHENIX Mid-rapidity extensions: Additional Tracking system and pre-shower Y. Akiba (RIKEN/RBRC) sPHENIX workfest July 29,
Heavy Flavor Measurements at RHIC&LHC W. Xie (Purdue University, West Lafayette) W. Xie (Purdue University, West Lafayette) Open Heavy Flavor Workshop.
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.
Jet fragmentation photons in ultrarelativistic heavy-ion collisions Koichi Hattori, Larry McLerran, Bjoern Schenke Quark Matter Sep Oct.
Non-Prompt J/ψ Measurements at STAR Zaochen Ye for the STAR Collaboration University of Illinois at Chicago The STAR Collaboration:
Jet Quenching of Massive Quark in Nuclear Medium Ben-Wei Zhang Institute of Particle Physics Central China Normal Univeristy ICHEP, Beijing --- Augest.
Review of ALICE Experiments
Probing QGP-medium interactions
F. Dominguez, CM, A. Mueller, B. Xiao and B. Wu, arXiv:
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.
Cyrille Marquet Columbia University
for the ALICE collaboration University of Tennessee at Knoxville
Strangeness Production in Heavy-Ion Collisions at STAR
Heavy-Flavour Physics in Heavy-Ion Collisions
ALICE and the Little Bang
Charm production at STAR
Status and Implications of PID measurements at high pT
Modification of Fragmentation Function in Strong Interacting Medium
Nanjing University of Sci. & Tech.
Identified Charged Hadron Production
Multiplicity Dependence of Charged Particle, φ Meson and Multi-strange Particle Production in p+p Collisions at
Shingo Sakai for PHENIX Collaborations (Univ. of Tsukuba)
GLOBAL POLARIZATION OF QUARKS IN NON-CENTRAL A+A COLLISIONS
用重味探测夸克胶子等离子体 Heavy Flavor as a Probe of Quark-Gluon Plasma
Presentation transcript:

M. Djordjevic 1 Heavy flavor suppression in a dynamical medium with finite magnetic mass Magdalena Djordjevic Institute of Physics Belgrade, University of Belgrade

M. Djordjevic 2 Overview Brief review of the dynamical energy loss Contribution to the energy loss due to longitudinally (electric) and transversely (magnetic) polarized gluons Introduction of finite magnetic mass Addressing heavy hlavor puzzle at RHIC Suppression predictions at the LHC

M. Djordjevic 3 Heavy flavour suppression Heavy (charm and beauty, M>1 GeV) flavour suppression is considered an excellent tool to study the properties of QGP. High pt suppression is a consequence of the energy loss. Reliable computations of energy loss mechanisms are needed.

We developed the radiative jet energy loss formalism in a finite size dynamical QCD medium. M. D., Phys.Rev.C80:064909,2009. M. D. and U. Heinz, Phys.Rev.Lett.101:022302,2008. Dynamical energy loss We computed the jet radiative energy loss in dynamical medium of thermally distributed massless quarks and gluons. Abolishes approximation of static scatterers.

M. Djordjevic 5 Dynamical v.s. static radiative energy loss 60% The energy loss in dynamical QCD medium is significantly larger than in static QCD medium. What is the origin of this increase?

M. Djordjevic 6 electric contribution magnetic contribution In dynamical medium both electric and magnetic contributions from the exchanged gluons contribute to the energy loss. Dynamical mediumStatic medium In static medium only electric contribution from the exchanged gluon contribute to the energy loss. electric contribution M.D.,J.Phys.G39:045007,2012

7 Magnetic v.s. electric contribution? Additional magnetic contibution is the reason for a significant increase of the radiative energy loss in dynamical medium. Electric and magnetic contributions to the energy loss are comparable in dynamical QCD medium M.D.,J.Phys.G39:045007,2012

M. Djordjevic 8 The dynamical energy loss formalism is based on HTL perturbative QCD, which requires zero magnetic mass. Finite magnetic mass? However, different non-perturbative approaches suggest a non-zero magnetic mass at RHIC and LHC. Can magnetic mass be consistently included in the dynamical energy loss calculations? Magnetic contribution to the energy loss depends on magnetic mass. How this inclusion would modify the energy loss results?

M. Djordjevic 9 Generalization of radiative jet energy loss to finite magnetic mass M.D. and M. Djordjevic, Phys.Lett.B709:229,2012 zero magnetic mass From our analysis, only this part gets modified. Finite magnetic mass:

10 A simple constraint on the magnetic mass If magnetic mass is larger than electric mass, the quark jet would, overall, start to gain (instead of lose) energy in this type of plasma. An apparent violation of the second law of thermodynamics. It is impossible to observe a plasma with magnetic mass larger than electric Various non-perturbative approaches suggest that, at RHIC and LHC, 0.4 < μ M /μ E < 0.6. M.D. and M. Djordjevic, Phys.Lett.B709:229,2012

M. Djordjevic 11 Finite magnetic mass effect Finite magnetic mass reduces the energy loss in dynamical QCD medium for 25% to 50%. CHARM

M. Djordjevic 12 Suppression at RHIC and LHC The numerical procedure includes: Both collisional and radiative energy loss from the newly developed (dynamical QCD medium) formalism Magnetic mass effects Multi-gluon fluctuations, i.e. the fact that energy loss is a distribution Path length fluctuations, i.e. the fact that particles travel different paths in the medium. M.D.,Phys.Rev.C85:034904,2012

D and B meson suppression at 200GeV Au+Au collisions at RHIC FONLL initial c and b pt disctributions Momentum discributions: W – S. Wicks, W. Horowitz,M.D.,M.Gyulassy,Nucl.Phys.A784:426,2007. D – A. Dainese,Eur.Phys.J.C33:495,2004. M. Djordjevic 13 M.D.,Phys.Rev.C85:034904,2012

14 Pion and single electron suppressions at 200GeV Au+Au collisions at RHIC M.D.,Phys.Rev.C85:034904,2012

D and B suppression at 2.76TeV Pb+Pb collisions at LHC FONLL initial c and b pt discributions 15

M. Djordjevic 16 Summary Dynamical energy loss formalism abolishes the approximation of static QCD medium. We extended the dynamical energy loss formalism to the finite magnetic mass. The extension suggests a limit on the magnetic to electric mass ratio. Dynamical QCD medium together with the finite magnetic mass was incorporated in the numerical procedure for suppression predictions. The predictions for RHIC and LHC indicate a reasonable agreement of the dynamical energy loss formalism with the available data.

Support Ministry of Science and Education in Serbia FP7 Marie Curie International Reintegration grant L’Oreal UNESCO For Women in Science Serbia

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2024 SlidePlayer.com Inc. All rights reserved.