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Charmonium spectrum at finite temperature from a Bayesian analysis of QCD sum rules. P. Gubler and M. Oka, Prog. Theor. Phys. 124 , 995 (2010). P. Gubler, K. Morita and M. Oka, in preparation. HNP 2011 POSCO International Conter, Pohang, Republic of Korea 21.2.2011
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Charmonium spectrum at finite temperature from a Bayesian analysis of QCD sum rules P. Gubler and M. Oka, Prog. Theor. Phys. 124, 995 (2010). P. Gubler, K. Morita and M. Oka, in preparation. HNP 2011 POSCO International Conter, Pohang, Republic of Korea 21.2.2011 Philipp Gubler (TokyoTech) Collaborators: Makoto Oka (TokyoTech), Kenji Morita (GSI)
Contents • QCD Sum Rules and the Maximum Entropy Method • Test of the method in the case of the ρmeson channel • Results of the analysis of charmonia at finite temperature • Conclusions
QCD sum rules M.A. Shifman, A.I. Vainshtein and V.I. Zakharov, Nucl. Phys. B147, 385 (1979); B147, 448 (1979). In this method the properties of the two point correlation function is fully exploited: is calculated “perturbatively”, using OPE spectral function of the operator χ After the Borel transformation:
The basic problem to be solved given ? “Kernel” (but only incomplete and with error) This is an ill-posed problem. But, one may have additional information on ρ(ω), which can help to constrain the problem: - Positivity: - Asymptotic values:
ρ(s) s The usual approach The spectral function is usually assumed to be describable by a “pole + continuum” form (ground state + excited states): This very crude ansatz often works surprisingly well, but… This ansatz may not always be appropriate. The dependence of the physical results on sth is often quite large.
The Maximum Entropy Method → Bayes’ Theorem likelihood function prior probability (Shannon-Jaynes entropy) Corresponds to ordinary χ2-fitting. “default model” M. Jarrel and J.E. Gubernatis, Phys. Rep. 269, 133 (1996). M.Asakawa, T.Hatsuda and Y.Nakahara, Prog. Part. Nucl. Phys. 46, 459 (2001).
Experiment: mρ= 0.77 GeV Fρ= 0.141 GeV A first test case: the ρmeson channel Prog. Theor. Phys. 124, 995 (2010). The sum rule: The position and residue of the ρ-meson are reproduced, but not its width.
Application to charmonium at finite temperature - Prediction of “J/ψSuppression by Quark-Gluon Plasma Formation” T. Matsui and H. Satz, Phys. Lett. B 178, 416 (1986). … - During the last 10 years, a picture has emerged from studies using lattice QCD (and MEM), where J/ψ survives above TC. (schematic) M. Asakawa and T. Hatsuda, Phys. Rev. Lett. 92 012001 (2004). S. Datta et al,Phys. Rev. D69, 094507 (2004). T. Umeda et al, Eur. Phys. J. C39S1, 9 (2005). … taken from H. Satz, Nucl.Part.Phys. 32, 25 (2006).
The charmonium sum rules at T=0 The sum rule: perturbative term including αs correction Non-perturbative corrections including condensates up to dim 6 Developed and analyzed in: M.A. Shifman, A.I. Vainshtein and V.I. Zakharov, Nucl. Phys. B147, 385 (1979); B147, 448 (1979). L.J. Reinders, H.R. Rubinstein and S. Yazaki, Nucl. Phys. B 186, 109 (1981). R.A. Bertlmann, Nucl. Phys. B 204, 387 (1982). J. Marrow, J. Parker and G. Shaw, Z. Phys. C 37, 103 (1987).
MEM Analysis at T=0 V PS mJ/ψ=3.12 GeV mηc=3.05 GeV Here, the following values were used:
The charmonium sum rules at finite T The application of QCD sum rules has been developed in: T.Hatsuda, Y.Koike and S.H. Lee, Nucl. Phys. B 394, 221 (1993). depend on T A non-scalar twist-2 gluon condensates appears due to the non-existence of Lorentz invariance at finite temperature: four-velocity of the medium
The T-dependence of the condensates The energy-momentum tensor is considered: After matching the trace part and the traceless part, one gets: obtained from lattice QCD These values are obtained from quenched lattice calculations: G. Boyd et al, Nucl. Phys. B 469, 419 (1996). taken from: O. Kaczmarek et al, Phys. Rev. D 70, 074505 (2004). K. Morita and S.H. Lee, arXiv:0908.2856 [hep-ph]. K. Morita and S.H. Lee, Phys. Rev. Lett. 100, 022301 (2008). K. Morita and S.H. Lee, Phys. Rev. C. 77, 064904 (2008).
The charmonium spectral function at finite T PS V Both J/ψ and ηc have melted completely.
Conclusions • We have shown that MEM can be applied to QCD sum rules • The “pole + continuum” ansatz is not a necessity • We could observe the melting of the S-wave charmonia using finite temperature QCD sum rules and MEM • Both ηc and J/ψ seem to melt between T ~ 1.0 TC and T ~ 1.1 TC,, which is below the values obtained in lattice QCD