23 Jun. 2010 Kenji Morita, GSI / XQCD2010 1 Mass shift of charmonium near Mass shift of charmonium near QCD phase transition and its QCD phase transition and its implication to relativistic implication to relativistic heavy ion collisions heavy ion collisions Kenji Morita Kenji Morita (GSI) (GSI) in Collaboration with in Collaboration with Su Houng Lee (Yonsei Univ.) Su Houng Lee (Yonsei Univ.) Gluon condensates in the hadronic environment near phase boundary Mass shift of J/and c from QCDSR Possible influences in statistical production
27
Embed
23 Jun. 2010Kenji Morita, GSI / XQCD20101 Mass shift of charmonium near QCD phase transition and its implication to relativistic heavy ion collisions Kenji.
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 1
Mass shift of charmonium near Mass shift of charmonium near QCD phase transition and its QCD phase transition and its
implication to relativistic heavy implication to relativistic heavy ion collisionsion collisions
Kenji Morita Kenji Morita (GSI) (GSI) in Collaboration with in Collaboration with
Su Houng Lee (Yonsei Univ.)Su Houng Lee (Yonsei Univ.)
Gluon condensates in the hadronic environment near phase boundary
Mass shift of J/ and c from QCDSR
Possible influences in statistical production
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 2
Our ApproachOur ApproachQCD sum rules with temperature dependent gluon condensatesQCD sum rules with temperature dependent gluon condensates
Condensates Spectral density
So far, pure gauge only
Gluon Condensates from lQCD
Dispersion relation + OptimizationOPE for 2-point
correlator
K.M and Lee, PRL100,PRC77,0908.2856
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 3
Gluon condensates in full Gluon condensates in full QCDQCD
In full QCD...In full QCD...
Additional quark contribution appears
and p can be obtained from lattice, but they contain the quark contribution also We want and p of gluonic sector
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 4
Implication from Nuclear Implication from Nuclear MatterMatterNuclear matter : full QCDNuclear matter : full QCD
Linear density approximation
Chiral Limit→Subtracting fermionic termMoment of gluon distribution function
→Picking up gluonic contribution
Cohen et al, PRC‘92
Klingl et al, PRL’99
Hayashigaki PTP’99
Density-dep. part
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 5
A Model for Gluon A Model for Gluon CondensatesCondensates
Extend previous expression to a resonance Extend previous expression to a resonance gas (w/ excluded volume correction)gas (w/ excluded volume correction)
Requirement : reproducing lattice EoS below Requirement : reproducing lattice EoS below TTcc with relevant hadronic degrees of with relevant hadronic degrees of freedomfreedom
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 6
mmii00
Hadron masses in the chiral limitHadron masses in the chiral limit SU(3)
AGi =0.9: assumed to be common
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 7
Fit to lattice dataFit to lattice data22 fit of v fit of v00 to EoS and Scalar condensate to EoS and Scalar condensate
Chemical potential leads to larger change of the gluon condensates
Lager mass shift in lower collision energy
(Andronic et al, NPA772)
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 9
Borel sum rule analysisBorel sum rule analysis
Flattest
Mmin : 30% Power corr.Mmax : 70% Pole dominance
T=156 MeV
B=403 MeV
v0=0
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 10
JJ//andandcc in hadronic matter in hadronic matter
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 11
JJ//andandcc in hadronic matter in hadronic matterRegarding v0=0 (0.54) as maximum (minimum)
10-50 MeV for J/
20-100 MeV for c
Largest at the smallest sNN
due to largest B
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 12
Charmonium ratio from stat. Charmonium ratio from stat. modelmodel
Independent of # of c-quarkIndependent of # of c-quark’ mass shift : unknown from QCDSR
2nd order Stark effect:
53 ~ 155 MeV
Consistent with experimental data
for small shift
J/ coming from c
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 13
SummarySummary
Modeling gluon condensates with Modeling gluon condensates with hadron gas : valid up to Thadron gas : valid up to T~~180 MeV180 MeVSizable mass shifts at freeze-out Sizable mass shifts at freeze-out points : from QCDSRpoints : from QCDSRLarger mass shift at high baryon Larger mass shift at high baryon densitydensityMass-shifted charmonium Mass-shifted charmonium generation via statistical generation via statistical hadronization may probe it.hadronization may probe it.
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 14
BackupBackup
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 15
Heavy Quarkonium as a Heavy Quarkonium as a Probe of DeconfinementProbe of Deconfinement
Heavy quarks : Heavy quarks : mmcc ~~ 1.5GeV, 1.5GeV, mmbb ~~ 4.7GeV 4.7GeV >> >> QCDQCD
No chiral symmetryQQbar states bound by
confinement force Successful description
by Coulomb+linear
potential
Change of the property : change of confinement property
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 16
Simplest model : free gasSimplest model : free gas
Only two parameters : Only two parameters : TT and and bb
Strangeness neutrality
Isospin symmetric matter
Other quantities follow from thermodynamicsOther quantities follow from thermodynamics
23 Jun. 2010 Kenji Morita, GSI / XQCD2010 17
Excluded volume correctionExcluded volume correctionReminder : Van-der-Waals EoSReminder : Van-der-Waals EoSRischke et al (’91): keep thermodynamic Rischke et al (’91): keep thermodynamic consistencyconsistency
Effectively, chemical potential is reduced→Repulsive interaction