Alberica Toia Physics Department CERN HGS-HIRe Lecture Week Manigod 24-31 January 2010 High Energy Dilepton Experiments Introduction.

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Alberica Toia Physics Department CERN HGS-HIRe Lecture Week Manigod January 2010 High Energy Dilepton Experiments Introduction

Alberica Toia 2 HGS-HIRe Lecture Week /10 Manigod Evolution of the Universe from the Big Bang to today’s world Nucleosynthesis builds nuclei up to He Nuclear Force…Nuclear Physics Universe too hot for electrons to bind E-M…Atomic (Plasma) Physics E/M Plasma Too hot for quarks to bind!!! Standard Model (N/P) Physics Quark- Gluon Plasma Too hot for nuclei to bind Nuclear/Particle (N/P) Physics Hadron Gas Solid Liquid Gas Today’s Cold Universe Gravity…Newtonian/General Relativity

Alberica Toia 3 HGS-HIRe Lecture Week /10 Manigod The “Little Bang” in the lab High energy nucleus-nucleus collisions: –fixed target (SPS: √s=20GeV) –colliders RHIC: √s=200GeV LHC: √s=5.5TeV QGP formed in a tiny region ( m) for very short time ( s) –Existence of a mixed phase? –Later freeze-out Collision dynamics: different observables sensitive to different reaction stages

Alberica Toia 4 HGS-HIRe Lecture Week /10 Manigod Probing the QGP penetrating beam (jets or heavy particles) absorption or scattering pattern QGP Rutherford experiment   atomdiscovery of nucleus l SLAC electron scatteringe  protondiscovery of quarks l Penetrating beams created by parton scattering before QGP is formed l High transverse momentum particles  jets l Heavy particles  open and hidden charm or bottom l Probe QGP created in Au+Au collisions l Calculable in pQCD l Calibrated in control experiments: p+p (QCD vacuum), p(d)+A (cold medium) l Produced hadrons lose energy by (gluon) radiation in the traversed medium l QCD Energy loss  medium properties l Gluon density l Transport coefficient probe bulk

Alberica Toia 5 HGS-HIRe Lecture Week /10 Manigod l Thermal black body radiation Real photons  Virtual photons  * which appear as dileptons  e  e   or     l No strong final state interaction l Leave reaction volume undisturbed and reach detector l Emitted at all stages of the space time development l Information must be deconvoluted Electromagnetic Radiation time hard parton scattering Au hadronization freeze-out formation and thermalization of quark-gluon matter? Space Time expansion Jet cc  e   p K   

Alberica Toia 6 HGS-HIRe Lecture Week /10 Manigod What we can learn from lepton pair emission Emission rate of dilepton per volume Boltzmann factor temperature EM correlator Medium property   ee decay Hadronic contribution Vector Meson Dominance qq annihilation Medium modification of meson Chiral restoration From emission rate of dilepton, one can decode medium effect on the EM correlator temperature of the medium arXiv: Thermal radiation from partonic phase (QGP) q q e+e+ e-e- e+e+ e-e- ++ -- 

Alberica Toia 7 HGS-HIRe Lecture Week /10 Manigod Relation between dilepton and virtual photon Emission rate of dilepton per volume Emission rate of (virtual) photon per volume Relation between them Virtual photon emission rate can be determined from dilepton emission rate For M  0, n  *  n  (real) real photon emission rate can also be determined M × dN ee /dM gives virtual photon yield Dilepton virtual photon Prob.  *  l + l - This relation holds for the yield after space- time integral arXiv:

Alberica Toia 8 HGS-HIRe Lecture Week /10 Manigod Theory prediction of dilepton emission Vacuum EM correlator Hadronic Many Body theory Dropping Mass Scenario q+q     ee (HTL improved) (q+g  q+    qee not shown) Theory calculation by Ralf Rapp at y=0, p T =1.025 GeV/c Usually the dilepton emission is measured and compared as dN/dp T dM The mass spectrum at low p T is distorted by the virtual photon  ee decay factor 1/M, which causes a steep rise near M=0 qq annihilation contribution is negligible in the low mass region due to the M 2 factor of the EM correlator In the caluculation, partonic photon emission process q+g  q+    qe + e - is not included 1/M  *  ee qq   *  e + e - ≈(M 2 e -E/T ) × 1/M arXiv:

Alberica Toia 9 HGS-HIRe Lecture Week /10 Manigod Virtual photon emission rate at y=0, p T =1.025 GeV/c Vacuum EM correlator Hadronic Many Body theory Dropping Mass Scenario q+q annihilation (HTL improved) The same calculation, but shown as the virtual photon emission rate. The steep raise at M=0 is gone, and the virtual photon emission rate is more directly related to the underlying EM correlator. When extrapolated to M=0, the real photon emission rate is determined. q+g  q+  * is not shown; it should be similar size as HMBT at this p T Real photon yield Turbide, Rapp, Gale PRC69,014903(2004) q+g  q+  * ? qq   * ≈M 2 e -E/T arXiv:

Alberica Toia 10 HGS-HIRe Lecture Week /10 Manigod The mass of composite systems mass given by energy stored in motion of quarks and by energy in colour gluon fields M   m i binding energy effect  atom m M » m i nucleon m atomic nucleus m M   m i binding energy effect  the role of chiral symmetry breaking chiral symmetry = fundamental symmetry of QCD for massless quarks chiral symmetry broken on hadron level

Alberica Toia 11 HGS-HIRe Lecture Week /10 Manigod left-handed right-handed Chirality l Chirality (from the greek word for hand: “  ”) when an object differs from its mirror image l simplification of chirality: helicity (projection of a particle’s spin on its momentum direction) l massive particles P l left and right handed components must exist l m>0  particle moves w/ v<c –P looks left handed in the laboratory –P will look right handed in a rest frame moving faster than P but in the same direction l chirality is NOT a conserved quantity l in a massless word l chirality is conserved –careful: m=0 is a sufficient but not a necessary condition

Alberica Toia 12 HGS-HIRe Lecture Week /10 Manigod l the QCD Lagrangian: QCD and chiral symmetry breaking free gluon field interaction of quarks with gluon free quarks of mass m n l explicit chiral symmetry breaking mass term m n  n  n in the QCD Lagrangian l chiral limit: m u = m d = m s = 0 l chirality would be conserved l  all states have a ‘chiral partner’ (opposite parity and equal mass) l real life a 1 (J P =1 + ) is chiral partner of  (J P =1 - ):  m ≈500 MeV even worse for the nucleon: N * (½ - ) and N (½ + ):  m ≈600 MeV l  (small) current quark masses don’t explain this l chiral symmetry is also spontaneously broken l spontaneously = dynamically

Alberica Toia 13 HGS-HIRe Lecture Week /10 Manigod l current quark mass l generated by spontaneous symmetry breaking (Higgs mass) l contributes ~5% to the visible (our) mass Origin of mass l constituent quark mass l ~95% generated by spontaneous chiral symmetry breaking (QCD mass)

Alberica Toia 14 HGS-HIRe Lecture Week /10 Manigod Chiral symmetry restoration l spontaneous symmetry breaking gives rise to a nonzero ‘order parameter’ l QCD: quark condensate ≈ -250 MeV 3 l many models (!): hadron mass and quark condensate are linked l numerical QCD calculations l at high temperature and/or high baryon density  deconfinement and  0 l approximate chiral symmetry restoration (CSR) l  constituent mass approaches current mass l Chiral Symmetry Restoration expect modification of hadron spectral properties (mass m, width  ) explicit relation between (m,  ) and ? l QCD Lagrangian  parity doublets are degenerate in mass

Alberica Toia 15 HGS-HIRe Lecture Week /10 Manigod l what are the best probes for CSR? requirement: carry hadron spectral properties from (T,  B ) to detectors l relate to hadrons in medium l leave medium without final state interaction l dileptons from vector meson decays best candidate:  meson –short lived –decay (and regeneration) in medium –properties of in-medium  and of medium itself not well known  meson (m  ≈2xm K )  ee/KK branching ratio! CSR and low mass dileptons m [MeV]  tot [MeV]  [fm/c] BR  e + e -  x  x  x 10 -4

Alberica Toia 16 HGS-HIRe Lecture Week /10 Manigod Dilepton Signal l Low Mass Region: m ee < 1.2 GeV/c 2 l Dalitz decays of pseudo-scalar mesons l Direct decays of vector mesons In-medium decay of  mesons in the hadronic gas phase l Intermediate Mass Region: 1.2 < m ee < 2.9 GeV/c 2 l correlated semi-leptonic decays of charm quark pairs l Dileptons from the QGP l High Mass Region: m ee > 2.9 GeV/c 2 l Dileptons from hard processes –Drell-Yan process –correlated semi-leptonic decays of heavy quark pairs –Charmonia –Upsilons  HMR probe the initial stage l Little contribution from thermal radiation LMR: m ee < 1.2 GeV/c 2 o LMR I (p T >> m ee ) quasi-real virtual photon region. Low mass pairs produced by higher order QED correction to the real photon emission o LMR II (p T <1GeV) Enhancement of dilepton discovered at SPS (CERES, NA60)

Alberica Toia 17 HGS-HIRe Lecture Week /10 Manigod Dilepton Signal II l Dileptons characterized by 2 variables: M, p T l M: spectral functions and phase space factors p T :p T - dependence of spectral function (dispersion relation) T - dependence of thermal distribution of “mother” hadron/parton M - dependent radial flow (   ) of “mother” hadron/parton Note I: M Lorentz-invariant, not changed by flow Note II: final-state lepton pairs themselves only weakly coupled l dilepton p T spectra superposition of ‘hadron-like’ spectra at fixed T early emission: high T, low  T late emission: low T, high  T final spectra from space-time folding over T-  T history from T i → T fo  handle on emission region, i.e. nature of emitting source mTmT 1/m T dN/dm T light heavy T purely thermal source explosive source T,  mTmT 1/m T dN/dm T light heavy

Alberica Toia 18 HGS-HIRe Lecture Week /10 Manigod HI low-mass dileptons at a glance l time scale of experiments = period of data taking ALICE (KEK E235) CERES DLS NA60 HADES CBM PHENIX

Alberica Toia 19 HGS-HIRe Lecture Week /10 Manigod HI low-mass dileptons at a glance l energy scale of experiments (KEK E235)CERESDLS NA60HADESCBMPHENIX 10158[A GeV] 17[GeV]√s NN 200 // ALICE [A TeV]