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Holographic description of heavy-ions collisions. Irina Aref’eva Steklov Mathematic al Institute , Moscow. 7th MATHEMATICAL PHYSICS MEETING: Summer School and Conference on Modern Mathematical Physics 9 - 19 September 2012, Belgrade, Serbia. Outlook.
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Holographic description of heavy-ions collisions Irina Aref’eva Steklov MathematicalInstitute, Moscow 7th MATHEMATICAL PHYSICS MEETING:Summer School and Conference on Modern Mathematical Physics 9 - 19 September 2012, Belgrade, Serbia
Outlook • Physical picture of formation of Quark-Gluon Plasma in heavy-ions collisions • Holography description of QGP in equilibrium • Holography description of heavy-ions collisions • New formula for multiplicity • Further directions
Quark-Gluon Plasma (QGP): a new state of matter QGP is a state of matter formed from deconfined quarks, antiquarks, and gluons at high temperature nuclear matter Deconfined phase QCD: asymptotic freedom, quark confinement T increases, or density increases 170 MeV 300 MeV
Experiments: Heavy Ions collisions produced a medium There are strong experimental evidences that RHIC or LHC have created some medium which behaves collectively: • modification of particle spectra (compared to p+p) • jet quenching • high p_T-suppression of hadrons • elliptic flow • suppression of quarkonium production HIC are studied in several experiments: • started in the 1990's at the Brookhaven Alternating Gradient Synchrotron (AGS), • the CERN Super Proton Synchrotron (SPS) • the Brookhaven Relativistic Heavy-Ion Collider (RHIC) • the LHC collider at CERN. Study of this medium is also related with study of Early Universe
Evolution of the Early Universe QGP in Heavy Ion Collision and Early Universe • One of the fundamental questions in physics is: what happens to matter at extreme densities and temperatures as may have existed in the first microseconds after the Big Bang • The aim of heavy-ion physics is to create such a state of matter in the laboratory. Evolution of a Heavy Ion Collision
The Standard Model of Nature 1. A Gauge Theory with a light Higgs for electro-weak and strong interactions. 2. General Relativity with a small Λ for gravity.
Theory. Heavy Ions collisions • Macroscopic: thermodynamics, hydrodynamics, kinetic theory, … • Fermi(1950); Pomeranchuk(1952); Landau(1953); Heisenberg(1952), • Rozental, Chernavskij (UFN,1954); • Landau, Bilenkij (UFN,1955); Feinberg (1972); • Cooper,…(1975); Bjorken(1983); 1950-th the hydrodynamic model to high energy collisions of protons Kolb, Heinz (2003); Janik, Peschansky (2006); Shuryak(,,,,, 2009); Peigne, Smilga (UFN, 2009) Dremin, Leonidov (UFN, 2010); Muller, Schafer(2011),…. Microscopic:- QCD, holographic (AdS/CFT) Application of holographic approach to formation of QGP is the subject of this talk
QGP in heavy-ions collisions There are strong experimental evidences that RHIC or LHC have created some medium: Elliptic flow more pressure along the small axis
Plot from: Alice Collaboration PRL, 2010 Multiplicity: Landau’s/Hologhrapic formula vs experimental data Landau formula Plot from: ATLAS Collaboration 1108.6027 Simplest Hologhrapic Model Modified Hologhrapic Model
Multiplicity s1/2NN dependence of the charged particle dNch/ dh | h =0 per colliding nucleon pair Npart/2 from a variety of measurements in p+p and p+-p and central A+A collisions, 0-5% centrality ALICE and CMS The curves show different expectations for the s1/2NN dependence in A+A collisions: results of a Landau hydrodynamics calculation (dotted line) ; an s0.15 extrapolation of RHIC and SPS data (dashed line); a logarithmic extrapolation of RHIC and SPS data (solid line)
Multiplicity in Landau model BACKUP Thermodynamic methods to investigating the process of high-energy collision. E. Fermi, Prog. Theor. Phys. 5, 570 (1950) Pomeranchuk, Dokl. Akad. Nauk SSSR, 78, 889 (1951) L. D. Landau, Izv. Akad. Nauk Ser. Fiz. 17, 51 (1953) To determine the total number of particles it is necessary to compute the entropy in the first moment of collision
QGP as a strongly coupled fluid • Conclusion from the RHIC and LHC experiments: appearance of QGP (not a weakly coupled gas of quarks and gluons, but a strongly coupled fluid). • This makes perturbative methods inapplicable • The lattice formulation of QCD does not work, since we have to study real-time phenomena. • This has provided a motivation to try to understand the dynamics of QGP through the gauge/string duality
“Holographic description of quark-gluon plasma” • Holographic description of quark-gluon plasma in equilibrium • Holography description of quark-gluon plasma formation in heavy-ions collisions
Holography and duality. Holography: ‘t Hooft, 1993; Susskind, 1994 Strings D=4 D=3 String theory on AdS5xS5 D=5 D=4 Gravity in AdS5 D=4 Gauge Theory Maldacena 1997: D=4 Gauge theory N=4 YM with SU(Nc) Duality: Group symmetry bosonic part SO(2,4) x SU(4) <-> isometries of AdS5xS5 conformal symmetry and R-symmetry
Dual description of QGP as a part of Gauge/string duality • There is not yet exist a gravity dual construction for QCD. • Differences between N = 4 SYM and QCD are less significant, when quarks and gluons are in the deconfined phase (because of the conformal symmetry at the quantum level N = 4 SYM theory does not exhibit confinement.) • Lattice calculations show that QCD exhibits a quasi-conformal behavior at temperatures T >300 MeV and the equation of state can be approximated by e= 3 p (a traceless conformal energy-momentum tensor). • The above observations, have motivated to use the AdS/CFT correspondence as a tool to get non-perturbative dynamics of QGP. • There is the considerable success in description of the static QGP. Review: Solana, Liu, Mateos, Rajagopal, Wiedemann, 1101.0618
AdS/CFT correspondence in Euclidean space. T=0 The correspondence between the strongly coupled N = 4 SYM theory in D=4 and classical (super)gravity on AdS5xS5 Simplest case: Witten;Gubser, Klebanov, Polyakov,1998 Renormalization IA, I.Volovich, PLB, 1998
AdS/CFT correspondence in Minkowski space. incoming wave at
AdS/CFT correspondence in Euclidean space. T=0 denotes Euclidean time ordering + requirement of regularity at horizon g:
-- retarded temperature Green function in 4-dim Minkowski AdS/CFT correspondence. Minkowski. T=0 QFT at finite temperature (D=4) Classical gravity with black hole (D=5) Son, Starinets, 2002 F -- kernel of the action for the (scalar) field in AdS5 LHS QFT with T Bogoliubov-Tyablikov Green function
AdS/CFT correspondence. T=0 Gravity: AdS5 with black hole RHS fk(z) is the solution to the mode equation: with unit boundary conditions:
Dual description of QGP as a part of gauge/string duality In the phenomenological hydrodynamical (Landau or Bjorken models of QGP), the plasma is characterized by a space-time profile of the energy-momentum tensor AdS/CFT: operators in the gauge theory correspond to fields in SUGRA . In the case of the energy-momentum tensor, the corresponding field is the 5D metric.
Dual description of QGP as a part of gauge/string duality Static uniform plasma Janik, 05 Solution: Performing a change of coordinates The standard AdS static black hole
Conclusion Today: 2001-2011 Black Hole in AdS5 static QGP in 4-dim • Formula for correlates • Static uniform plasma BH AdS Tomorrow: 2008-now • formation of QGP formation of BH in AdS
D=2 CFT at T=0 and BTZ black hole Backup 2D CFT Euclidean finite temperature correlates of the local operator with conformal dimension Conformal map from the infinite plane to the cylinder with circumference L=1/T (*)
D=2 CFT at T=0 and BTZ black hole Backup Gravity calculations
Backup D=2 CFT at T=0 and BTZ black hole On shell Boundaries: (**)
Backup D=2 CFT at T=0 and BTZ black hole tIdentification of the prefactors Retarded Green’s (**) taken at are equal to the expression givenby eq. (*)
BACKUP Relation between Bogoliubov-Tyablikov GR and Matsubara GE Green functions Bogoliubov-Tyablikov Matsubara denotes Euclidean time ordering