Pion condensation and the QCD phase diagram at finite isospin density

Proceedings of XIII Quark Confinement and the Hadron Spectrum — PoS(Confinement2018) Pub Date : 2018-09-30 DOI:10.22323/1.336.0197

J. Andersen, P. Adhikari, Patrick Kneschke

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引用次数: 4

Abstract

We use the Polyakov-loop extended two-flavor quark-meson model as a low-energy effective model for QCD to study 1) the possibility of inhomogeneous chiral condensates and its competition with a homogeneous pion condensate in the $\mu$--$\mu_I$ plane at $T=0$ and 2) the phase diagram in the $\mu_I$--$T$ plane. In the $\mu$--$\mu_I$ plane, we find that an inhomogeneous chiral condensate only exists for pion masses lower that 37.1 MeV and does not coexist with a homogeneous pion condensate. In the $\mu_I$--$T$ plane, we find that the phase transition to a Bose-condensed phase is of second order for all values of $\mu_I$ and we find that there is no pion condensation for temperatures larger than approximately 187 MeV. The chiral critical line joins the critical line for pion condensation at a point, whose position depends on the Polyakov-loop potential and the sigma mass. For larger values of $\mu_I$ these curves are on top of each other. The deconfinement line enters smoothly the phase with the broken $O(2)$ symmetry. We compare our results with recent lattice simulations and find overall good agreement

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有限同位旋密度下的介子凝聚和QCD相图

我们使用polyakov环扩展双味夸克-介子模型作为QCD的低能有效模型，研究了1)在$\mu$—$\mu_I$平面T=0$时非均匀手性凝聚的可能性及其与均匀介子凝聚的竞争;2)$\mu_I$—$T$平面的相图。在$\mu$—$\mu_I$平面中，我们发现介子质量低于37.1 MeV时存在不均匀手性凝聚，且不与均匀介子凝聚共存。在$\mu_I$—$T$平面中，我们发现对于所有$\mu_I$的值，向玻色凝聚相的相变都是二阶的，并且我们发现在大于大约187mev的温度下没有介子凝聚。手性临界线与介子凝聚的临界线在某一点相连，该点的位置取决于波利亚科夫环势和sigma质量。对于较大的$\mu_I$值，这些曲线彼此重叠。解界定线平滑地进入具有破坏的$O(2)$对称性的相位。我们将我们的结果与最近的晶格模拟进行了比较，发现总体上很一致

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Proceedings of XIII Quark Confinement and the Hadron Spectrum — PoS(Confinement2018)

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