Introduction to Relativistic Heavy Ion Collision Physics Huan Z. Huang 黄焕中 Department of...
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Transcript of Introduction to Relativistic Heavy Ion Collision Physics Huan Z. Huang 黄焕中 Department of...
Introduction to Relativistic Heavy Ion Collision Physics
Huan Z. Huang
黄焕中Department of Physics and Astronomy
University of California, Los Angeles
Two Puzzles of Modern Physics
• Missing Symmetry – all present theories are based on symmetry, but most symmetry quantum numbers are NOT conserved.
• Unseen Quarks – all hadrons are made of quarks, yet NO individual quark has been observed.
-- T.D.Lee李政道
Vacuum As A Condensate
• Vacuum is everything but empty! • The complex structure of the vacuum and the
response of the vacuum to the physical world breaks the symmetry.
• Vacuum can be excited!
We do not understand vacuum at all !
A Pictorial View of Micro-Bangs at RHIC
Thin PancakesLorentz =100
Nuclei pass thru each other
< 1 fm/c
Huge StretchTransverse ExpansionHigh Temperature (?!)
The Last Epoch:Final Freezeout--
Large Volume
Au+Au Head-on Collisions 40x1012 eV ~ 6 micro-Joule
Human Ear Sensitivity ~ 10-11 erg = 10-18 Joule
A very loud Bang, indeed, if E Sound……
Vacuum Engineering !
initial state
pre-equilibrium
QGP andhydrodynamic expansion
hadronization
hadronic phaseand freeze-out
High Energy Nucleus-Nucleus Collisions
Physics: 1) Parton distributions in nuclei 2) Initial conditions of the collision 3) a new state of matter – Quark-Gluon Plasma and its properties 4) hadronization
RHIC Complex
STAR
Relativistic Heavy Ion Collider --- RHIC
Au+Au 200 GeV N-N CM energyPolarized p+p up to 500 GeV CM energy
Salient Feature of Strong Interaction
Asymptotic Freedom: Quark Confinement:
庄子天下篇 ~ 300 B.C. 一尺之棰,日取其半,万世不竭
Take half from a foot long stick each day,You will never exhaust it in million years.
QCD q q
q qq q
Quark pairs can be produced from vacuumNo free quark can be observedMomentum Transfer
Co
up
lin
g S
tren
gth
Shorter distance
(GeV)
QCD on Lattice
Transition from quarks to hadrons – DOF !QGP – not an ideal Boltzmann gas !
Lattice: current statusLattice: current status• technical progress: finer mesh size, physical quark masses, improved
fermion actions phase-transition: smooth, rapid cross-over EoS at finite μB: in reach, but with large systematic uncertainties
critical temperature: TC180 MeV
Rajagopal & Wilczek, hep-ph/0011333
Fodor & Katz, hep-lat/0110102
Quark-Hadron Phase Transition
The Melting of Quarks and Gluons-- Quark-Gluon Plasma --
Matter Compression: Vacuum Heating:
High Baryon Density-- low energy heavy ion collisions-- neutron starquark star
High Temperature Vacuum -- high energy heavy ion collisions -- the Big Bang
Deconfinement
Collision Dynamics
Initial Energy Density EstimatePRL 85, 3100 (00); 91, 052303 (03); 88, 22302 (02), 91, 052303 (03)
PHOBOS
hminus:Central Au+Au <pT>=0.508GeV/cpp: 0.390GeV/c
Pseudo-rapidityWithin ||<0.5 the total transverse momentum created is 1.5x650x0.508 ~ 500 GeV from an initial transverse overlap area of R2 ~ 153 fm2 !
Energy density ~ 5-30 0 at early time =0.2-1 fm/c !
19.6 GeV
130 GeV200 GeV
Ideas for QGP Signatures
Strangeness Production: (J.Rafelski and B. Muller PRL 48, 1066 (1982))
s-s quark pair production from gluon fusions in QGP leads to strangeness equilibration in QGP most prominent in strange hyperon production (and anti-particles).
Parton Energy Loss in a QCD Color Medium:(J.D. Bjorken Fermilab-pub-82-059 (1982) X.N. Wang and M. Gyulassy, PRL 68, 1480 (1992))
Quark/gluon
Quark/gluon dE/dx in color medium is large!
Ideas for QGP Signatures
Chiral Symmetry Restoration: T = 0, m(u,d,s) > 0 – Spontaneous symmetry breaking T> 150 MeV, m=0 – Chiral symmetry restored Mass, width and decay branching ratios of resonances may be different in dense medium .
QCD Color Screening: (T. Matsui and H. Satz, Phys. Lett. B178, 416 (1986))
A color charge in a color medium is screened similar to Debye screening in QED the melting of J/.
c c Charm quarks c-c may not bindInto J/ in high T QCD medium
The J/ yield may be increased due to charm quark coalescence at the final stage of hadronization (e.g., R.L. Thews, hep-ph/0302050)
1st year detectors
Silicon Vertex Tracker
Central Trigger Barrel
FTPCs
Time Projection Chamber
Barrel EM Calorimeter
Vertex Position Detectors
Endcap Calorimeter
Magnet
Coils
TPC Endcap & MWPC
+ TOF
Silicon Strip Detector
ZDC
2nd year detectors installation in 2002 installation in 2003
ZDC
The STAR Detector