Xin-Nian Wang/LBNL QCD and Hadronic Physics Beijing, June 16-20, 2005 Xin-Nian Wang 王新年 Lawrence Berkeley National Laboratory Jet Tomography of Strongly Interacting QGP
Xin-Nian Wang/LBNL QCD phase transition Asymptotic freedom Confinement scale anomaly (break scale invariance)
Xin-Nian Wang/LBNL Lattice QCD results F. Karsch ‘2001
Xin-Nian Wang/LBNL Medium Response Dynamic System: Photon or dilepton emission (McLerran & Toimela’85) J/ suppression (Matsui & Satz’86) QCD Response:Parton scattering (Gyulassy & XNW’92)
Xin-Nian Wang/LBNL Jet Quenching & Modified Fragmentation e-e- Guo & XNW’00
Xin-Nian Wang/LBNL Non-Abelian LPM Effect Two-parton correlation: Landau- Pomeranchuck-Migdal interference: i j Formation time
Xin-Nian Wang/LBNL Quadratic Nuclear Dependence
Xin-Nian Wang/LBNL HERMES data E. Wang & XNW 2000
Xin-Nian Wang/LBNL Parton Energy Loss BDPM Gyulassy Vitev Levai Wang & Wang Wiedemann; Zakharov Quark energy loss = energy carried by radiated gluon
Xin-Nian Wang/LBNL HERMES data in Au nuclei E. Wang & XNW 2000
Xin-Nian Wang/LBNL Jet Quenching at RHIC
Xin-Nian Wang/LBNL Geometry of dense matter Non-central collisions Azimuthal asymmetry jet
Xin-Nian Wang/LBNL Dihadron Correlation p T trig =4-6 GeV p T =2-4 GeV Pedestal&flow subtracted trigger
Xin-Nian Wang/LBNL Away-side suppression trigger
Xin-Nian Wang/LBNL Elliptic flow of a perfect fluid Pressure gradient anisotropy Hydrodynamic calculation with =0
Xin-Nian Wang/LBNL Jet Remnants Induced Bremsstrahlung: MM Cherenkov radiation Pedestal&flow subtracted
Xin-Nian Wang/LBNL 3-D Tomography Global polarization w.r.t. Nuclear reaction plane xx Z.-T. Liang, XNW PRL 94 (2005)102301
Xin-Nian Wang/LBNL Summary Discovery of Jet Quenching at RHIC proves that a interacting dense matter is formed: Opaque to jets Dense matter at RHIC is 30 times higher than cold nuclei, energy density is 100 times higher Collective behavior: Hydrodyamic limit strongly interactive QGP Jet tomography a useful and power tool for studying properties of dense matter –Heavy quarks, dihadron correlation, angular distribution, flavor dependence …
Xin-Nian Wang/LBNL
Angular distribution of radiative gluons Radiation in vacuum Induced Bremsstrahlung: Further interaction of the radiated gluons with the medium?
Xin-Nian Wang/LBNL Di-hadron fragmentation function h1h1 h2h2 jet Majumder & XNW
Xin-Nian Wang/LBNL Modification of the dihadron distribution Pedestal&flow subtracted STAR preliminary Effect of longitudinal flow C. Salgado z
Xin-Nian Wang/LBNL Sonic Boom MM Trigger Casalderrey-Solana, Shuryak and Teaney Linearize disturbance
Xin-Nian Wang/LBNL Future of Jet quenching STAR preliminary +jet correlation in Au+Au in run4? More accurate determination of initial Et
Xin-Nian Wang/LBNL Modification for Heavy Quarks (1) Slow clock for formation time Djordjevic & Gyulassy Zhang & XNW Armesto,Dainese, Salgado & Wiedemann (2) Color factor (3) Dead cone effect E Q < E g, E q Zhang & XNW
Xin-Nian Wang/LBNL Energy Dependence of quenching D. d’Enterria, Hard Probes 2004
Xin-Nian Wang/LBNL Effect of non-Abelian energy loss Eg=EqEg=Eq E g =2 E q Qun Wang & XNW nucl-th/ Eskola Honkanen Salgado Wiedemann Fixed p T =6 GeV
Xin-Nian Wang/LBNL No suppression in d+Au STAR PHENIX
Xin-Nian Wang/LBNL High pt spectra in Au+Au H. Zhang,E. Wang J. Owens, XNW 2005
Xin-Nian Wang/LBNL High pt spectra in pp collisions H. Zhang J. Owens E. Wang XNW 2005
Xin-Nian Wang/LBNL Charm quark Large charm quark Suppression? Hadronic scattering?
Xin-Nian Wang/LBNL Parton recombination Hwa; Fries Particle or parton correlations are not trivial