Lattice Gauge Theory for the Quark-Gluon Plasma

1. Lattice Gauge Theory for the Quark-Gluon Plasma Sourendu Gupta TIFR

2. Particles in the Standard Model (1990s) Tuesday Talk: S. Gupta

3. The Eightfold Way (variables) Tuesday Talk: S. Gupta

4. The Eightfold Way (variables) Tuesday Talk: S. Gupta

5. The Eightfold Way (variables) Tuesday Talk: S. Gupta

6. The Eightfold Way (variables) Tuesday Talk: S. Gupta

7. The basics of extreme matter • Normal matter made of baryons • Baryons contain 3 quarks and interact by exchanging mesons • Mesons contain 2 quarks • When you squeeze this matter by applying pressure (or heating it up) you get matter with large numbers of quarks • This is the quark gluon plasma Tuesday Talk: S. Gupta

8. Quark matter factories • Create an universe through a big bang and let it cool • Create a supernova and let its core collapse into a really compressed star • Bang some (relatively) large chunks of matter together very hard • Think hard … you may get a patent Tuesday Talk: S. Gupta

9. The RHIC at Brookhaven Tuesday Talk: S. Gupta

10. Normal matter needs QED or its effective theories There are many phases of normal matter Normal matter may be neutral or a plasma Normal matter may be a solid, liquid or a gas Quark matter needs QCD or its effective theories There are many phases of quark matter Quark matter may be neutral or a plasma Quark matter is fluid: either gas or liquid On quark matter Tuesday Talk: S. Gupta

11. Droplets from Colliders Tuesday Talk: S. Gupta

12. Gas or Liquid? Difference is in flow Tuesday Talk: S. Gupta

13. How to pro(b/v)e a liquid • Show that there is some matter • …count the number of particles coming out of the collision and compute density • Show that this generates pressure • …elliptic flow: Bhalerao’s talk • Does the pressure cause coherent velocities? • …detailed analysis of spectra and flow • Is the flow turbulent? Tuesday Talk: S. Gupta

14. How to predict its properties • Need to use quantum field theory • Equation for fields due to Maxwell • Equation for matter due to Dirac • ∞ first found by Lorentz (self interaction of point particle) • ∞ in the quantum theory: Heisenberg, Bethe • Removed by Feynman, Schwinger, Tomonaga • Modern formulation by Wilson: unifying field theory and statistical mechanics Tuesday Talk: S. Gupta

15. The bubbling vacuum Quantum fluctuations: t  h/2 Particles can be produced from vacuum for a short time … and disappear again (if no one is looking) Mobile charges  the vacuum screens No one measures the charge of an electron without the screening cloud: it is actually ∞ and cancels Lorentz’s ∞ This affects the mass: gauge symmetry Tuesday Talk: S. Gupta

16. Charge renormalization: screening in QED Tuesday Talk: S. Gupta

17. Anti-screening in QCD Asymptotic freedom is anti-screening: the opposite of electrodynamics Tuesday Talk: S. Gupta

18. Numerical renormalization • Solve coupled differential equations: Maxwell + Dirac • Do it many times: quantum theory is a sum over possibilities (Feynman) • Do it on a lattice (spacing d): no infinities in solid state physics • e changes with d Can do large e ! Tuesday Talk: S. Gupta

19. The phase diagram • Several phases • Several 1st order transitions • More than one critical point • More variables not shown: tri-critical points… Tuesday Talk: S. Gupta Rajarshi Ray

20. Flow parameters • P(T) or P(T,): relativistic gas • Equation of state is either E(P) or E(P,N) • Speed of sound • Specific heat • Compressibility • Viscosity Swagato Mukherjee Tuesday Talk: S. Gupta

21. Lots more to do… • Analogues of Debye screening for pions, strange and charmed particles, causing them to dissolve • Photon emission rates: is the plasma a black body? Are there plasmons? • Supersonic shock waves: jets of particles travel with speed of light through the plasma • Quantum coherence created as particles freeze out of the plasma • Anything else you can think of… Tuesday Talk: S. Gupta