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The Phase Diagram of Nuclear Matter Oumarou Njoya

The Phase Diagram of Nuclear Matter Oumarou Njoya. Outline. Motivations for studying QCD phase transitions Introduction to QCD Mapping the phase diagram Experimental considerations Summary. Motivations. The Big bang Theory Neutron stars Discovery of strong force.

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The Phase Diagram of Nuclear Matter Oumarou Njoya

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  1. The Phase Diagram of Nuclear MatterOumarou Njoya

  2. Outline • Motivations for studying QCD phase transitions • Introduction to QCD • Mapping the phase diagram • Experimental considerations • Summary

  3. Motivations • The Big bang Theory • Neutron stars • Discovery of strong force

  4. Forces and structures in Nature Gravity one “charge” (mass)‏ force decreases with distance m1 m2 Electromagnetism two “charges” (+ / -)‏ force decreases with distance Atom + - + +

  5. quark Atomic nuclei and the “nuclear” force Nuclei composed of: protons (+ electric charge)‏ neutrons (no electric charge)‏ Do not fly apart!? “nuclear force” overcomes electrical repulsion determines nuclear reactions(stellar burning, bombs…)‏ arises from fundamental strong force (#3)‏ acts on color charge of quarks neutron proton

  6. What is QCD? Quantum chromo-dynamics A theory of the strong (or nuclear, or color) force. Closely modeled on QED but with three conserved color charges: Quarks: r, g, b Anti quarks: anti-red, anti-green, anti-blue. Quarks scatter by exchanging gluons, which carry color and anticolor.

  7. More QCD Only colour singlet states can exist as free particles. Hadrons are colour singlet. Mesons: Baryons: Confinement (r ~ 1fm) Chiral symmetry Having to do with quark masses Asymptotic freedom (r → 0) Strong interaction becomes weaker at high energy Relativistic hot gas

  8. quark-antiquark pair created from vacuum Confinement to study structure of an atom… electron nucleus neutral atom Confinement: fundamental & crucial (but not well understood!) feature of strong force - colored objects (quarks) have  energy in normal vacuum… QCD quark Strong color field Energy grows with separation !!! “white” 0 (confined quarks)‏ “white” proton “white” proton (confined quarks)‏

  9. QCD Thermodynamics Relativistic kinematics of free gas. Partition function: bosons fermions

  10. A simple model • Ideal gas of massless pions. Stefan-Boltzmann

  11. From hadrons to quarks and gluons • Chiral symmetry argument • Massless u and d implies chirally symmetric Lagrangian. Spontaneous symmetry breaking in ground state. • Symmetry conserved at high T. • Expect phase transition. (akin to Curie point in a ferromagnet). • Pisarski-Wilzeck: 1st order transition • Tricritical point • Evidence suggests 1st order at high T and low μB • At low T: nuclear matter

  12. Crossover and critical point • Crossover for μB = 0. (Lattice QCD) • Critical point • Coexisting phases along 1st order line, similar to that of liquid in condensed matter physics • Low-T high- μB: ordered quark phases exist

  13. Locating the critical point • Theoretically simple (singularity of partition function). • Importance sampling and sign problem. • Lattice QCD.

  14. Lattice QCD • There are two order parameters • Quarks and gluons are studied on a discrete space-time lattice • Solves the problem of divergences in pQCD calculations (which arise due to loop diagrams)‏ • The lattice provides a natural momentum cut-off • Recover the continuum limit by letting a 0 pure gauge = gluons only

  15. Order Parameters Deconfinement measure: Palyokov loop Effective quark mass Energy density є at deconfinement

  16. The phase diagram of QCD Early universe quark-gluon plasma critical point ? Tc Temperature hadron gas nucleon gas nuclei 0 Neutron stars vacuum baryon density

  17. Generating a deconfined state Present understanding of Quantum Chromodynamics (QCD)‏ heating compression deconfined color matter Hadronic Matter (confined)‏ Nuclear Matter (confined)‏ Quark Gluon Plasma deconfined !

  18. PHOBOS BRAHMS RHIC PHENIX STAR AGS TANDEMS Relativistic Heavy Ion Collider (RHIC)‏ 1 km v = 0.99995c = 186,000 miles/sec

  19. A few methods • Hadron radiation • Electromagnetic radiation • Dissipation of a passing quarkonyum beam (fancy for Debye screening in nuclear matter) • Energy loss of a passing jet.

  20. Hadron radiation • Formed at the transition surface between hot matter and physical vacuum. • At Tc local hadronization occurs. Mostly pions, kaons, nucleons and anti-nucleons. • Study of relative abundances gives us information about hadronization temperature.

  21. Electromagnetic radiation • Spectra of photons and leptons provide information about the state of the medium at the time they were formed. • Consider for illustration μ+μ- formation

  22. Summary • Mapping the QCD phase diagram is important for understanding the early evolution of the universe and the physics of neutron star. • QCD thermodynamics suggests a well-defined transition from hadronic matter to a plasma of deconfined quarks and gluons. • The nature and the origin of the transition at high needs to be clarified further. • The properties of the QGP can be explored through hard probes. Certainly, lots of new physics await discovery.

  23. Bibliography • M. Stephanov, [arXiv:hep-lat/0701002v1] • Helmut Satz, [arXiv:0903.2778v1 [hep-ph]] • Peter G Jones, Introduction to QCD, rhic.physics.wayne.edu/~bellwied/classes/phy7070/QCD-lecture.ppt • Slides 5,8,17,18 were borrowed from Gang Wang (UCLA).

  24. Thank you!

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