The QCD Vacuum, Hadrons and Superdense Matter

The following sections are included:

• Contents

• Preface

The following sections are included:

• Gauge fields
  • Gauge “symmetry”
  • Gauge fields on the lattice
  • Fixing the gauge
  • Hamiltonian quantization
  • Rotator — a toy model for periodic coordinates

• Road to QCD
  • Quarks and the “colors”
  • Renormalizability and asymptotic freedom

• Path integrals and Euclidean time
  • Green functions and Feynman path integrals
  • Perturbation theory and Euclidean path integrals
  • Numerical evaluation of Euclidean path integrals

• Gauge fields on the lattice
  • Renormalization group and asymptotic freedom
  • Continuum limit of lattice gauge theory
  • Path integrals for fermions

• Light quarks and symmetries of QCD
  • Exact and approximate symmetries of QCD
  • Chiral anomalies, the UV approach
  • Chiral anomalies, the IR approach
  • Other applications of chiral anomalies
  • Scale anomaly

• Heavy quarks, new symmetry and effective theory

• Changing the number of colors N_c
  • Large number of colors
  • QCD with the smallest (N_c = 2) number of colors

The following sections are included:

• Phenomenology of the hadronic world
  • Brief history
  • The “usual” hadrons
  • The “unusual” mesons
  • The exotic hadrons
  • Remarks about highly excited states

• Models of hadronic structure
  • Generalities
  • MIT bag
  • Skyrmions
  • Chiral bags
  • Evolving views on the nature of the spin forces

• Models of the QCD vacuum: an overview
  • Condensates and scales
  • Condensate factorization and stochastic vacuum model
  • An example of a highly inhomogeneous model: the instanton vacuum

• Chiral symmetry breaking and effective low energy theory
  • Spontaneous breaking of the chiral symmetry
  • The Goldstone modes: oscillators of the quark condensate
  • Quark condensate and Dirac eigenvalue spectrum
  • Elements of chiral perturbation theory
  • Effective chiral Lagrangian
  • Nambu–Jona–Lasinio model

• Color confinement
  • Static potential
  • Dual superconductivity
  • Structure of flux tubes
  • Interaction of flux tubes

The following sections are included:

• Tunneling in quantum mechanics
  • Brief history of tunneling
  • Double-well problem and instantons
  • Pre-exponent and zero modes
  • Instanton gas
  • Two-loop quantum corrections

• A digression: tunneling versus perturbative series
  • Convergence of perturbative series
    • Dyson instability
    • Perturbative series in high orders
    • Semiclassical evaluation of Dyson's instability
    • High orders of perturbative series in field theories
  • Instanton–anti-instanton interaction and one more correction to the ground state energy

• Fermions coupled to the double-well potential

• Instantons in gauge theories
  • Topologically nontrivial objects
  • Topologically distinct pure gauge configurations
  • Digression: spherically symmetric Yang–Mills fields
  • Static magnetic configurations and their minimal energy

• Tunneling and BPST instanton
  • Instanton solution
  • Theta vacua
  • Tunneling amplitude

The following sections are included:

• Brief history of instantons
  • Discovery and early applications
  • Phenomenology leads to a qualitative picture
  • Technical development during 1980s
  • Recent progress
  • Instantons at finite temperatures and chiral restoration
  • Instantons and color superconductivity at high densities

• Tunneling and light quarks
  • Relating gauge field topology to the axial charge
  • Fermionic zero modes
  • The 't Hooft effective interaction
  • Baryon number violation in the standard model

• Instanton ensemble
  • Qualitative discussion of the instanton ensembles
  • Mean field approximation: pure glue
  • Quark condensate in the mean field approximation
  • The single instanton approximation

• The interacting instanton liquid model
  • Screening of the topological charge

• Instantons for larger number of colors
  • Naive counting and expectations
  • Mean field arguments and the chiral condensate
  • Fluctuations in the interacting instanton liquid
  • Do instantons cluster at large N_c?

The following sections are included:

• Generalities
  • Brief history
  • Lattice limitations
  • Mesoscopic regime and the random matrix theory
  • Art of numerical simulation of multi-dimensional integrals

• Fermions on the lattice
  • Fermionic doublers
  • Wilson fermions
  • Ginsparg–Wilson relation and lattice chiral symmetry
  • Known solutions to GW relation
  • Domain wall fermions

• Hadronic spectroscopy on the lattice
  • Glueballs in gluodynamics
  • Light quark spectroscopy in quenched approximation
  • Spectroscopy with dynamical quarks

• Topology on the lattice
  • Quantum-mechanical topology and perfect actions
  • Naive and geometric methods for gauge fields
  • Are the lowest Dirac eigenstates locally chiral?
  • Testing the large N_c limit on the lattice

The following sections are included:

• Generalities
  • Why the correlation functions?
  • Different representations of the correlation functions
  • Quantum numbers and inequalities
  • Correlators with chirality flips

• Phenomenology of mesonic correlation functions
  • Vector and axial correlators
  • Comparing axial and vector channels
  • Pseudoscalar SU(3) octet (π, K, η) channels
  • SU(3) singlet pseudoscalars
  • Hadron–parton duality

• Operator product expansion and QCD sum rules
  • Brief history and overview
  • Separation of scales
  • OPE in a background field
  • Sum rules for heavy–light mesons
  • OPE for light quark baryons
  • OPE for mesons made of light quarks

• Instantons and the correlators: analytic results
  • Propagator in the field of a single instanton
  • First order in the 't Hooft effective vertex
  • Propagator in the instanton ensemble
  • Propagator in the mean field approximation
  • Correlators in the random phase approximation

• Correlators in the instanton liquid
  • Quark propagator in the instanton liquid
  • Mesonic correlators
  • Baryonic correlation functions
  • Comparison to correlators on the lattice
  • Gluonic correlation functions

• Hadronic structure and n-point correlators
  • Wave functions
  • Form factors

The following sections are included:

• Introduction
  • Reggions and the Pomeron
  • High energy collisions in pQCD and its “phases”
  • Evolving descriptions of soft Pomeron dynamics

• Instanton-induced processes at high energies
  • Toward the “holy grail”
  • Exciting a quantum system from under the barrier
  • Semiclassical production of sphaleron-like clusters
  • Explosion of the turning states
  • Semiclassical evaluation of the cross section
  • Semiclassical Wilson lines
  • Pomeron from instantons

• Pomeron structure and interactions
  • Clustering in inclusive pp collisions
  • Inclusive production of clusters in double-Pomeron processes
  • Exclusive production of hadrons in double-Pomeron processes

The following sections are included:

• Introduction
  • Brief history and the basic scales
  • From field theory to thermodynamics
  • A quantum particle at finite T
  • Gauge and fermion fields at finite T

• QCD at high temperatures
  • Screening versus anti-screening
  • Thermodynamical potential in the lowest order
  • Ring diagram re-summation
  • IR divergences in general
  • Are perturbative series useful in practice?
  • HTL re-summations and the quasiparticle gas
  • Viscosity of the QGP

• Hadronic matter
  • Pion gas at low T
  • Resonance gas
  • Pion liquid

• QCD phase transitions at finite T
  • Deconfinement
  • Chiral symmetry restoration
  • Static quark potential at high T
  • Equation of state in the transition region

• Instantons at finite T
  • Finite temperature field theory and the caloron solution
  • Instanton density at high temperature
  • Instantons at low temperature
  • Chiral symmetry restoration and instantons
  • Instanton ensemble in the phase transition region
  • Critical behavior in the instanton liquid

• Hadronic correlation functions at finite temperature
  • Screening masses
  • Temporal correlation functions
  • U(1)_A breaking at high T

The following sections are included:

• Introduction
  • Toward the macroscopic limit
  • “Little Bang” versus Big Bang
  • Experimental centers, present and future
  • Mapping the phase diagram

• Relativistic hydrodynamics
  • Equations of the ideal hydrodynamics
  • Dissipative terms
  • The Bjorken solution
  • Further simplifications and solutions
  • Singularities: shocks, rarefaction waves, and the “explosive edge”

• Chemical and thermal freezeouts
  • Why two freezeouts?
  • Chemical freezeout
  • Between chemical and kinetic freezeouts
  • Thermal freezeout
  • After freezeout
  • Freezeout of resonances and nuclear fragments
  • Resonance modification

• Hydrodynamic description of heavy ion data
  • A long road to unveiling the transverse flow
  • Qualitative effects of the QCD phase transition
  • Solutions to hydrodynamic equations
  • Radial flow at SPS and RHIC
  • Elliptic flow
  • Limits to ideal hydrodynamics

• Interferometry of identical secondaries or HBT method
  • Main idea of the method
  • Correlator and random source model
  • Issue of “coherency” and long-lived resonances
  • Expanding sources and regions of homogeneity

• Correlation of non-identical hadrons
  • Ordering the production time for all hadronic species
  • Balance functions

• Event-by-event fluctuations
  • Fluctuations of hadronic cross sections are surprisingly large
  • All heavy ion collisions are (about) the same!
  • Critical opalescence near the tricritical point
  • Can QGP charge fluctuations survive the hadronic phase?

The following sections are included:

• Penetrating probes: dileptons and photons
  • Basic rates and space–time profile
  • Dilepton data versus expectations
  • Direct photon production

• Quarkonia in heavy ion collisions
  • Charmonium suppression, the mechanisms
  • Charmonium suppression, the data
  • φ-related puzzles

• Evolving views on the initial stage
  • Perturbative processes and minijets
  • Classical fields in heavy ion collisions
  • Non-perturbative equilibration and topological clusters
  • Dilemma of weakly versus strongly coupled QGP

• Jet quenching
  • Jet quenching in experiment
  • Azimuthal asymmetry at large p_t
  • Radiation in matter
  • Synchrotron-like QCD radiation

The following sections are included:

• From nuclear to quark matter
  • Nuclear matter
  • Other phases of nuclear matter?
  • From nuclear to quark matter
  • Chiral waves and chiral crystals

• Compact stars
  • Brief introduction
  • Phases of matter in compact stars

• Color superconductivity in very dense quark matter
  • Brief introduction to superconductivity
  • BCS pairing and Gorkov abnormal Green functions
  • Three mechanisms of quark pairing
  • Magnetic pairing in asymptotically dense matter
  • Instanton-induced color superconductivity
  • Two-flavor QCD: 2SC phase
  • Three-flavor QCD: CFL phase
  • Excitations of color superconductor
  • Quark matter with charge neutrality and realistic m_s
  • Open questions

The following sections are included:

• Hadronic world in alternative or changing universe

• Increasing the number of quark flavors: the first window to conformal world

• supersymmetric theories
  • Instantons and exact beta function
  • N_c−N_f phase diagram: SUSY versus QCD

• supersymmetric theories

• supersymmetric theories and AdS/CFT correspondence
  • Conformal field theory
  • A window to the tring world: strong coupling
  • AdS/CFT duality at weak coupling and instantons

The following sections are included:

• APPENDIX A: Notations
  • Some abbreviations used
  • Units
  • Space–time and other indices, standard matrices
  • Properties of η symbols
  • Gauge fields
  • Quark fields
  • QCD feynman rules

• APPENDIX B: Basic Instanton Formulae
  • Instanton gauge potential
  • Fermion zero modes and overlap integrals
  • Group integration

• APPENDIX C: A Sample Program for Numerical Simulation of the Euclidean Quantum Paths

• Bibliography

• Index