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Properties of spin-1/2 heavy baryons at nonzero temperature

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arxiv 2107.05209 v3 pith:TOS52MWQ submitted 2021-07-12 hep-ph hep-exhep-lat

Properties of spin-1/2 heavy baryons at nonzero temperature

classification hep-ph hep-exhep-lat
keywords baryonstemperaturemassresidueheavyoperatorspropertiesresults
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The spectroscopic properties of single heavy spin-1/2 $\Lambda_{Q}$, $\Sigma_{Q}$, $\Xi^{(\prime)}_{Q}$ and $ \Omega_{Q}$ baryons are investigated at finite temperature in the framework of thermal QCD sum rule. We discuss the behavior of the mass and residue of these baryons with respect to temperature taking into account contributions of non-perturbative operators up to dimension eight. We include additional operators coming from the Wilson expansion due to breaking the Lorentz invariance at non-zero temperature. The obtained results show that the mass of these baryons remain stable up to roughly $T=108$ MeV while their residue are unchanged up to $T=93$ MeV. After these points, the mass and residue start to diminish by increasing the temperature. The shifts in the mass and residue for both the bottom and charm channels are considerably large and we observe the melting of these baryons near to the pseudo-critical temperature determined by recent lattice QCD calculations. We present our results for the mass of these baryons with both the positive and negative parity at $ T\rightarrow 0 $ limit, which are consistent with the existing theoretical predictions as well as experimental data.

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