relativistic heavy ion physics: heavy quarks and quarkonia
DESCRIPTION
Relativistic Heavy Ion Physics: Heavy Quarks and Quarkonia. James Nagle. CTEQ Summer School Lecture #2 - June 8, 2002. University of Colorado, Boulder. Studying Quark Deconfinement. Lattice QCD results show that the confining potential between heavy quarks is screened at high temperature. - PowerPoint PPT PresentationTRANSCRIPT
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James Nagle
CTEQ Summer SchoolLecture #2 - June 8, 2002
Relativistic Heavy Ion Physics:
Heavy Quarks and Quarkonia
Relativistic Heavy Ion Physics:
Heavy Quarks and Quarkonia
University of Colorado, Boulder
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Studying Quark DeconfinementStudying Quark Deconfinement
Color Screening
cc
Lattice QCD results show that the confining potential between heavy quarks is screened at high temperature.
This screening should suppress bound states such as J/.
r
V(r
)/
Lattice QCD calculation
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ThermometerThermometer
The ’ and c melt below or at Tc
the J/melts above Tc and eventually the (1s) melts.
Different states “melt” at different temperatures due to different binding energies.
state J/ c
' (1s) b
(2s) b' (3s)
Mass [GeV} 3.096 3.415 3.686 9.46 9.859 10.023 10.232 10.355B.E. [GeV] 0.64 0.2 0.05 1.1 0.67 0.54 0.31 0.2
Td/Tc --- 0.74 0.15 --- --- 0.93 0.83 0.74
hep-ph/0105234 - “indicate ’ and the c dissociate below the deconfinement point.”
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Drell-Yan BaselineDrell-Yan BaselineAt CERN-SPS energies, Drell-Yan dominates the dimuon invariant mass spectrum above the J/ and ‘.Drell-Yan provides a good baseline for J/ suppression that should scale with binary collisions since the photon does not interact with the medium.
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Charm NormalizationCharm NormalizationAt RHIC, Drell-Yan is not easily measured because it is dominated by leptons from open charm above the ’.
Shadowing of initial state partons means that one must compare J/ production with something that couples directly to the gluons(eg. Charm, Beauty).
RHICSPS
LHC
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More Charm InterestMore Charm InterestIn addition, total charm production may be affected not just in a factorized shadowing picture, but from the saturation of gluons in a Color Glass Condensate.
Is there thermal or simple secondary scattering charm production after the initial parton-parton scattering?
Could large thermal charm production lead to J/ enhancement via c-cbar coalescence?
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Charm and JetsCharm and Jets
Radiative quark energy loss is qualitatively different for heavy and light quarks.
More massive charm quarks move slower and this leads to suppression of co-linear gluon emission (“dead-cone” effect)
Suppression of Suppression = NO Suppression
Predict enhanced D/ ratio
cc
D
D
Y.L.Dokshitzer and D.E. Kharzeev, hep-ph/0106202
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Charm DiagramCharm Diagram
0E.g. D K
0eD K
0D K
0 0e eD D e e K K
0 0eD D e K K
0 0D D K K
c c
0D
0D
For example:
Direct reconstruction of open Direct reconstruction of open charm is ideal, but difficult.charm is ideal, but difficult.
Open charm and bottom can be Open charm and bottom can be measured through single leptons measured through single leptons and lepton pairs.and lepton pairs.
K+
K-
e+
e
-
D*0
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Charm via ElectronsCharm via ElectronsHigh pT single electrons were observed at the ISR in the early 1970’s
F. W. Busser et al., PLB 53, 212 F.W.Busser et al., NPB 113, 189
These electrons were later interpreted as a signal from semi-leptonic decays of open charm
I.Hunchlife and C.H.Llewellyn Smith, PLB 61,472
M. Bourquin and J.-M.Gaillard, NPB 114,334
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Direct D ReconstructionDirect D ReconstructionDirect charm measurement in hadron-hadron collisions has proved to be quite challenging.
Using D* reconstruction and displaced vertex measurements have allowed observations at FNAL and CERN.
Extrapolation of p-p data at lower energies to RHIC 130 GeV yields
cc = 380 120 b
Systematic error should probably be somewhat larger.
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Measuring CharmMeasuring CharmPHENIX recorded 2 million Au-Au events in Run I, and can thus address charm production via single electrons.
D0 K- +
Charm
Beauty
Drell-Yan
0, Dalitz
conversions
Simulation of single electronsD0 K- e+ e
One must account for contributions:
0, Dalitz conversions
Remaining signal is then from open charm and open beauty Drell-Yan thermal production new physics
B0 D- e+ e
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PHENIX Pioneering High Energy Ion eXperiment
PHENIX Pioneering High Energy Ion eXperiment
Designed to measure electrons, muons, photons and hadrons.
Complex set of four separateparticle spectrometers.
This requires many different types of detector technologies and an integrated electronics readout.
Yellow beam
Blue beam
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Electron Needle in a Hadron HaystackElectron Needle in a Hadron Haystack
View from North Side
South Side
East Arm West Arm
6 PMT RICH ring2.55 GeV/c track2.5 GeV EMCal hitelectron candidate
EMCal
RICHPC1
DC
EMCal
RICHPC1
DC
TOF
TECPC3
PHENIX Spectrometer
PHENIX is designed to find1 electron out of 10,000 pions !
Electron identification:– track reconstructed
(momentum p)– ring found in Ring Imaging
Cherenkov Counter (velocity threshold)– energy cluster found in Electro-magnetic Calorimeter (energy E)
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PHENIX PicturePHENIX Picture
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Total Electron YieldTotal Electron Yield
0 ee
ee, ee
0ee, 3
0ee, ee
conversion
ee
ee
Transverse Momentum (GeV/c)
Electron Yield per Event
ElectronsBackground
ElectronsAllratio
""
.
Systematic Error
Transverse Momentum (GeV/c)
Many electrons are from light hadron decays, and must be subtracted off to see the charm contribution.
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Charm ResultsCharm Results
PYTHIA model is tuned to match lower energy charm production data.
PYTHIA shows good agreement with charm production that scales with the number of binarycollisions.
Transverse Momentum (GeV/c)
Electron Yield per Event
Clear remaining electron signal observed that appears consistent with semi-leptonic decays of charmed D mesons.
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Binary ScalingBinary ScalingSurprisingly good agreement with assumption of binary collision scaling and extrapolated proton-proton charm cross section at 130 GeV.
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Charm Cross SectionCharm Cross SectionWe estimate the charm yield by assuming that all single electrons above “background” are from D mesons. Neglect other possible sources such as thermal dileptons, etc.By fitting the single electron distribution, we obtain:
Data is consistent with binary scaling (no nuclear or medium effects), but with large uncertainties.
Errors - statistical uncertainty (14%), fitting range (18%), background subtraction (44%), PYTHIA kT (11%), D+/D0 (13%). Additional uncertainty in the total charm cross section from PDF in the charm rapidity distribution.
NbinaryCentrality dcc/dy|y=0(b) cc(b)
0-10%
0-92%
90564
24616
971349107863
38060200
42033250
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Proton-Nucleus StudiesProton-Nucleus Studies
cc
E769 250 GeV ± PRL 70,722 (1993)
WA82 340 GeV - PRB 284,453 (1992) Vogt et al., NP 383,643 (1992)
E769 250 GeV -
WA78 320 GeV - (Beam dump)
D meson production inproton-Nucleus and -Nucleus collisions at lower energies is consistent with binary collision scaling ( = 1). ANA
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Theoretical CalculationTheoretical Calculation
Z.Lin, R. Vogt, X-N. Wang PRC 57 (1998)
Charm =340 b
Charm w/ dE/dx=-2 GeV/fm
Theoretical prediction for electrons from charm.Inclusion of energy loss at the same scale as for light quarks.
Why is the calculation withno energy loss different from the PYTHIA result?
Different fragmentation function used in
calculation.
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D Meson ContributionsD Meson ContributionsThe three types of D mesons that contribute single electrons are:
name b.f. DeX percentage contribution to electrons in PYTHIAD+ 17.2% 21.6%D0 7.7% 66.8%D+
S 8.0% 11.6%
Note that most all excited charm mesons do not decay semi-leptonically, but only contribute via sequential decayD*+ D0 + 68.3%
D+ 0 30.6%D+ 1.1%
D*0 D0 0 61.9%D0 38.1%
D+/D0 = 0.32 (PYTHIA) gives an average b.f. DeX of 9.7%PHENIX paper uses D+/D0 = 0.65 0.35 which gives b.f. DeX of 11.0%Theory prediction of Lin, Vogt, Wang uses b.f. DeX of 12.0%
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Fragmentation FunctionsFragmentation Functions
z
bm
z
zz
zczf T
aa
2
exp11
)(
Lund symmetric fragmentation function (PYTHIA default)
z
bm
z
zz
zczf T
aa
bmR QQ
2
1exp
11)( 2
2)131)( zaazf 2
11
1
1)(
zzz
czfQ
Quark mass dependence is in the mT
Bowler modification “since LUND predicts a somewhat harder B meson spectrum than observed in data.”
Other options are:
Field-Feynman (for light quarks) Peterson (for heavy quarks)
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Comparing FunctionsComparing Functions
Light quarks (u,d)blue = Fields-Feynmanblack dash = Lund fragmentation
z
dN
/dz
* z
Heavy quarks (c,b)red = Peterson functionblack dash = Lund fragmentation
Bowler correction not shown(1-z) is obvious
For charm quarks, the Peterson and Lund fragmentation roughly agree and give an average <z> ~ 0.8.
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Intrinsic CharmIntrinsic Charm
Dashed = (1-z) function Solid = Peterson function
For example, in R. Vogt, Brodsky, Hoyer, “Systematics of Charm Production”, Nucl. Phys. B383, 643 (1992), they discuss a model where large xF D mesons are dominantly produced by intrinsic charm pairing with co-moving valence quarks.
- + A at 250 GeV- (u d)
D+ (c d)
D- (c d)
Charm quark is not sloweddown in combining withnearby d quark. Thus more D- than D+ at high xF.
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Electron InversionElectron InversionGoing beyond the PHENIX data, one can invert the single electrons to calculate a D meson spectrum.
1) Power Law Form
2) Guassian Form
Both forms are agree with limited statistics PHENIX data from Run1.
Work withSean Kelly
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D/ ?D/ ?
0 x 10
PYTHIA output
PHENIX D/ is a factor of 2-3 larger than from PYTHIA model tuned to lower energy charm data.
We must replace PYTHIA with PHENIX p-p data for and D with Run 2 data ! Then we will see.
PHENIX 0 x 10
p-p with binary scaling
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Hydrodynamics? Or Fragmentation
Hydrodynamics? Or Fragmentation
If we assume that there is large pressure build up in the partonic phase, charm quarks may participate in hydrodynamic expansion. This could also happen in the hadronic stage via D meson scattering.Simply taking the hydrodynamic model parameters from matching the PHENIX , K, p, one calculates the D meson pT spectra.
We then calculate the single electrons and find good agreement. Remember there is a free normalization.
Best hydro parameters+/-2 parameters
Work with Sotiria Batsouli
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Alternate Inversion MethodAlternate Inversion Method
pT (e) = 0.45
pT (e) = 0.85pT (e) = 1.50
One can invert the electrons point by point to a D meson yield integrated above some pT minimum. Much greater statistics from Run 2 should help discriminate between these models.
Distribution of D mesons that contribute to different electron bins.
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Many Lepton ChannelsMany Lepton Channels
D0 K- +
D0 K- e+ e
D0 K- +
B0 D- +
B0 D- e+ e
B0 D- +
D0D0 +- K+ K-
D0D0 e+e- K+ K- ee
D0D0 +e- K+ K- e
Future measurements of single leptons at higher momentum will have large contributions from Beauty decays.
Also correlated leptons provide additional constraints and very different backgrounds.
Finally, future RHIC upgrades with inner silicon detectors may allow for displaced vertex measurements to tag the heavy meson decays.
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J/ ProductionJ/ Production
Quarkonium states are not directlyproduced, but have pre-cursor states.Color Octet Model (COM) necessaryto explain J/ production at high pT
measured by CDF at the Tevatron.
F. Abe et al., Phys. Rev. Lett. 79, 3867 (1997).Kramer, hep-ph/0106120
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Nuclear AbsorptionNuclear AbsorptionThe octet state can break-up with nucleons in the colliding nuclei with ccg-N~ 6-7 mb and for the singlet state cc-N~2 mb
After a proper timethe J/ or ’ state is formed. After that the break-up cross section for the ’ is larger due to the lower binding energy.
J/ and ’ should have similar absorption if ccg > crossing
cfmm QCDcgcc /3.02 2/1
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Proton-Nucleus ModelingProton-Nucleus Modeling
• Model includes both octet and singlet state contributions.• Require 8-1 = 0.02 fm/c, much smaller than expected !• Still shows disagreement with E866 data.
• Energy dependent breakup
and small 8-1 results in matching the large xF observed nuclear suppression.
Arleo, Gossiaux, Gousset, Aichelin, hep-ph/9907286
4.0
)( 108
GeV
sNcc
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Nucleus-Nucleus CollisionsNucleus-Nucleus CollisionsWe must understand the normal absorption of the J/ or its precursor state in normal nuclear matter.
(1) break-up by nucleons in the colliding nuclei can be studiedusing p-A collisions
(2) break-up by co-moving hadrons in the produced fireballis calculated to be small, but calculations vary a lot!
beforePre-resonance absorption
Quarkonium statein bath of hadrons
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CERN Press Release 2000CERN Press Release 2000http://press.web.cern.ch/Press/Release00/PR01.00EQuarkGluonMatter.html
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NA50 Suppression ResultNA50 Suppression Result
“Strong evidence for the formation of a transient quark-gluon phase without color confinement is provided by the observed suppression of the charmonium states J/, c, and ’.”
Maurice Jacob and Ulrich Heinz
NA50 at the CERN-SPS
Discontinuity due to c melting
Drop due to J/ melting
Using Drell-Yan as control*
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Model BiasModel BiasMike Bennett and I find good agreement with their data in theET resolution range 55-75% /(ET)
Easy to create an inflection point exactly where they see one.
No systematic error included by NA50 for energy resolution,Glauber model parameters, transverse energy scaling.
Ratio of 55%/75% calculatedNb versus ET
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Charm Enhancement !Charm Enhancement !Intermediate mass region (IMR) dimuons are thought to have a large open charm contribution. NA50 observes an enhancement of IMR relative to Drell-Yan, which scales with binary collisions. This may imply a charm enhancement by x3.5 over binary scaling in central Pb+Pb collisions !
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Future Measure at RHICFuture Measure at RHICAt RHIC, PHENIX can measure quarkonia in the electron and muon channel. We have first low statistics data on tape. Future running at high luminosity will be required for a definitive measurement. STAR will also add a measurement in the electron channel at high pT.
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PHENIX CoveragePHENIX Coverage
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Conclusions, so far...Conclusions, so far...RHIC appears to be creating a hot, dense and expanding state of deconfined QCD matter
All results so far consistent (but not conclusive) with this interpretation
• initial conditions - saturated gluon distributions from color glass condensate
• energy density - exceeds lattice QCD expectations• plasma state - large parton scattering for hydrodynamic
expansion• hard probes - parton energy loss from deconfined medium
RHIC experiments have two orders of magnitude more data in Run II. More stringent tests required of models.Polarized proton-proton data taking just completed. Exciting years ahead of physics discovery !
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High Intensity Future AwaitsHigh Intensity Future Awaits
FY2000(66 GeV/amu)
FY2001 – 02100 GeV/amu
PHENIX during last 10 days:24 (b)-1/week
Lave(week) = 0.4 1026 cm-2 s-1
Lave(week)/Lave(store) = 27 %