1. Thermal modification of bottomonium spectral functions from QCD sum rules with the maximum entropy method
Kei Suzuki (Tokyo Institute of Technology)
Philipp Gubler (RIKEN)
Kenji Morita (YITP)
Makoto Oka (TITech, KEK)
Thank you for the introduction and the opportunity to make today’s this presentation .
I’d like to talk about quarkonium suppression and QCD sum rules. My collaborators are Mr. Gubler and Mr. Moirita and Mr. Oka.
P. Gubler, K. Morita, and M. Oka, Phys. Rev. Lett. 107, (2011)
K. Suzuki, P. Gubler, K. Morita, and M. Oka, arxiv: , to be published in NPA

2. Xth Quark Confinement and the Hadron Spectrum
Outline of Our Work
・Background Quarkonium melts in quark gluon plasma (QGP) ー
・Purpose
　To investigate melting temperature
First, I’ll overview our research. As a background knowledge, it is well known that the quarkonium melts in the quark gluon plasma. This famous phenomena are called “quarkonium suppression’’. And Our purpose is to investigate about quarkonium melting temperatures. Then, as a method to achieve this purpose, we use QCD sum rules and MEM.
・Method
　QCD sum rules with MEM
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3. Outline of Today’s Talk
Introduction
1-1. Quarkonium suppression
1-2. Previous work
2. Methods
Results
3-1. Charmonium
3-2. Bottomonium
3-3. Bottomonium excited states
4. Summary
T=? ー
T=? ー
I’d like to outline of today’s talk. First, I will introduce quakonium suppression and its previous work . And, Secondly, as a method, I explain QCD sum ruled for quyarkonium. And thirdly, I’ll report about results for charmonium and bottomonimu and bottomoinumu excited states. Finally, I’ll summarize.
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Xth Quark Confinement and the Hadron Spectrum

4. Xth Quark Confinement and the Hadron Spectrum
1. Introduction
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5. Quarkonium suppression
T. Matsui and H. Satz, Phys. Lett. B178, 416 (1986), T. Hashimoto et al. , Phys. Rev. Lett. 57, 2123 (1986)
Quarkonium suppression
Quarkonium (J/Ψ,Υ etc.) dissociates in QGP
⇒A signal of QGP matter? ー
Quarkonium suppression is the famous phenomenon in QGP. This phenomenon is well known as a signal of QGP. And, then, it is interesting that a variety of quarkonium have different melting temperatures . Therefore, by comparing with different melting temperature,s this phenomona are expected as a thermometer for QGP.
Different melting temperatures between a variety of quarkonium (J/Ψ,ηc,Υ…）
⇒Thermometer for QGP!!
Taken from K. Fukushima and T. Hatsuda,
Rept. Prog. Phys. 74, (2011)
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6. Previous work (Theory)
M. Asakawa and T. Hatsuda,
Phys. Rev. Lett. 92, (2004)
Lattice QCD with MEM
J/Ψ ηc
J/Ψ
⇒J/Ψ and ηc melt at 1.6Tc
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7. Previous work (Theory)
G. Aarts et al., JHEP 1111 (2011) 103
Lattice QCD + NRQCD with MEM Υ
First peak survives and second peak disappears. This behavior shows that~
⇒Excited state Υ(2S) melts at lower temperature than ground state Υ(1S)
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8. Previous work (Experiment)
S. Chatrchyan et al. [CMS Collaboration], arxiv:
Heavy ion collisions at the LHC (CERN)
Υ(1S)
Υ(2S,3S)
⇒Excited states Υ(2S), Υ(3S) melt at lower temperature than ground state Υ(1S)
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9. Xth Quark Confinement and the Hadron Spectrum
2. Methods
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10. Theoretical approach for quarkonium suppression
How can we describe quarkonium suppression from QCD? ⇒We study temperature dependence of spectral function
Quarkonium correlation function
Spectral function of hadron state
Non-perturbative
QCD approach
T-dependence input
T-dependence output
latticeQCD, QCD sum rule etc. m t
ρ(t)
First, As theoretical approach for quarkonium suppression, we study temperature dependence of spectral functions. Generaly speaking, if one calculate quarkonium correlation function, then, by using non-perturbative QCD approach, one can obtain spectral functions of hadrons. And, we input temperature depedence into left side, and we can output temperature dependence of spectral functions. Namely, at zero temperature, we should get the peak of spectral functions, and at finite temperature,
we will investigate the behavior of peaks. In the next slide, I’ll explane QCD sum rules.
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11. Xth Quark Confinement and the Hadron Spectrum
QCD sum rule
M.A. Shifman, A.I. Vainshtein, and V.I. Zakharov,
Nucl. Phys. B147, 385 (1979); B147, 448 (1979)
QCD sum rule
Relation between operator product expansion (OPE) of correlation function and spectral function of hadron m t
ρ(t)
Borel transformation
QCD sum rules is relation between hadron~
However, because in the left side, OPE lost some information, so, in the right side, we need some assumption. In the Conventional QCD sum rules approaches, we assume phenomenological assumption, namely “pole+continuum’’. In this time, we don’t use these assumption. Instead, in order to estimate possible functional form, we used MEM.
Output spectral function with MEM
Input OPE
One hadron state
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12. Xth Quark Confinement and the Hadron Spectrum
Quarkonium OPE
A. Bertlmann, Nucl. Phys. B204, 387 (1982）
Temperature dependence
・1st term → Free correlator
・2nd term → αs correction
・3rd term → Scalar gluon condensate
・4th term → Twist-2 gluon condensate ー
This expression is quarkonium OPE. This OPE consists of four terms.
Attractive
Repulsive at finite T ー
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13. Xth Quark Confinement and the Hadron Spectrum
OPE ＋ ＋ ＋ ＋ ＋ ＋
・3rd-term＋4th-term (Gluon condensates)
Especially, 3rd term and 4th term, namely gluon condensate terms, these coefficients of gluon condensate are inversely proportional to 4th power of quark mass. So, these coefficients generate different melting temperatures between charmonium and bottomonium.
⇒Coefficients of gluon condensates are inversely proportional to m4
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14. Temperature dependence of gluon condensates
Gluon condensates at finite temperature are expressed as energy density ε and pressure p
We Input ε and p from quenched lattice QCD
So, these behaviors of gluon condensates cause the quarkonium suppression.
⇒Gluon condensates decrease
　with increasing temperature
K. Morita and S.H. Lee, Phys. Rev. Lett. 100, (2008); Phys. Rev. C 77, (2008)
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15. Xth Quark Confinement and the Hadron Spectrum
3. Results
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16. Charmonium at zero temperatureΥ ηb
J/Ψ ηc
Mass=3.06GeV exp.)3.10GeV Mass=3.02GeV exp.)2.98GeV
The obtained masses are consistent with experimental values of ground state mass.
χc0
χc1
Mass=3.36GeV exp.)3.42GeV Mass=3.50GeV exp.)3.51GeV
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17. Charmonium at finite temperatureー
J/Ψ ηc
disappear at T=1.2Tc disappear at T= Tc
χc0
χc1
The peak of spectral function gradually decrease and disappear at about 1.2Tc.
disappear at T= Tc disappear at T= Tc
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18. Bottomonium at zero temperatureΥ ηb
Mass=9.63GeV exp.)9.46GeV Mass=9.55GeV exp.)9.39GeV
Obtained masses is higher than the experimental values of the ground state masses.
So, these gaps are due to contributions of the excited states. Namely, these peaks contain ground and excited states.
χb0
χb1
Mass=10.18GeV exp.)9.86GeV Mass=10.44GeV exp.)9.89GeV
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19. Bottomonium at finite temperatureー Υ ηb
survive up to T>2.5Tc survive up to T>2.5Tc
χb0
χb1
At the finite temperature, in the case of upsilon and eta_b, these peaks survive up to 2.5T_c. On the other hand, x_c0 and x_c1 are disappear at T= T_c.
disappear at T= Tc disappear at T= Tc
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20. Bottomonium excited states
The obtained bottomonium spectral functions include contributions of excited states
To investigate behavior of the excited states, we analyzed “residue’’ (integral value) of peak
We used least squares fitting to exclude contributions of continuum
(one peak + continuum as Breit-Wigner + step-like function)
Υ(1S,2S,3S) states are mixed Υ
・Our method cannot
separate these states
Next, we will discuss about bottomonium excited states. As I have mentioned before, the obtained bottomonium spectral functions contain contributions of excited states.
This result is the next slide.
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21. Temperature dependence of residue
Υ(1S+2S+3S)
Υ(1S) only?
This analyze
And at 1.5Tc to 2.0Tc, the residue suddenly decrease
Finally, at 3.0Tc, the some residue survive. And, this residue corresponds to upsilon(1S) only.
Obtained residue of Υ peak decreases with increasing temperature
⇒Excited states(2S, 3S) melt at Tc and ground state(1S) survives?
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22. Xth Quark Confinement and the Hadron Spectrum
Summary
We extracted melting temperature of quarkonia from QCD sum rules with MEM
Melting temperatures of quarkonia
Our results suggested that bottomonium excited states Υ(2S,3S) melt at lower temperature than ground state Υ(1S)
J/Ψ ηc
χc0
χc1
1.2Tc Tc Tc Υ ηb
χb0
χb1
>2.5Tc Tc
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23. Xth Quark Confinement and the Hadron Spectrum
Outlook
We will investigate contribution of 2nd order αs correction ⇒These change melting temperatures?
As a next outlook, we will investigate contributions of 2nd order alpha_s corrections like these diagrams. And, we will discuss whether or not these corrections change melting temperature. This calculation is in preparation and coming soon. That’s all. Thank you for your kind attention.
Coming Soon!
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24. Previous Work (Theory）
Potential model
　⇒Υ(1s) survive at T>4.0Tc
　⇒Υ(2s) melts at T～1.60Tc
　⇒Υ(3s) melts at T～1.17Tc
　⇒Υ(1s) melts at T～4.10Tc
　⇒Υ(2s) melts at T～1.38Tc
　⇒χb melt at T～1.18Tc
Spectral function with complex potential
　⇒Υ(1s) melts at T～2.2Tc
H. Satz, J. Phys. G32 (2006) R25
S. Digal, O. Kaczmarek, F. Karsch, H. Satz, Eur. Phys. J. C43 (2005) 71
C.-Y.Wong Phys. Rev. C72 (2005)
P. Petreczky, C. Miao, and A. Mocsy, Nucl.Phys. A855 (2011) 125
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25. MEM analysis of mock data
To confirm reproducibility of MEM, We input δ function and exp. value
mass shift
Information of excited states remain as residue or mass shift
3 peaks are combined into a single peak
⇒This method cannot separate multiple states
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26. Charmonium at finite temperature
P. Gubler, K. Morita, and M. Oka,
Phys. Rev. Lett. 107, (2011)
T=1.2Tc
T=1.1Tc
T=1.0Tc
T=0.9Tc
J/Ψ
⇒J/Ψ melts at 1.2Tc
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27. Residue analysis (least squares fitting)
Continuum intrude peak at finite temperature
⇒Fitting function is ①Breit-Wigner + continuum
　　　　　　　　　②Gaussian + continuum
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