Large \(N_c\) QCD phase diagram at \(\mu _B=0\)

IF 2.6 3区 物理与天体物理 Q2 PHYSICS, NUCLEAR The European Physical Journal A Pub Date : 2024-09-02 DOI:10.1140/epja/s10050-024-01400-9
T. D. Cohen, L. Ya Glozman
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Abstract

Lattice studies suggest that at zero baryon chemical potential and increasing temperature there are three characteristic regimes in QCD that are connected by smooth analytical crossovers: a hadron gas regime at \(T < T_{ch}\sim 155\) MeV, an intermediate regime, called stringy fluid, at \(T_{ch}< T < \sim 3 T_{ch}\), and a quark-gluon plasma regime at higher temperatures. These regimes have been interpreted to reflect different approximate symmetries and effective degrees of freedom. In the hadron gas the effective degrees of freedom are hadrons and the approximate chiral symmetry of QCD is spontaneously broken. The intermediate regime has been interpreted as lacking spontaneous chiral symmetry breaking along with the emergence of new approximate symmetry, chiral spin symmetry, that is not a symmetry of the Dirac Lagrangian, but is a symmetry of the confining part of the QCD Lagrangian. While the high temperature regime is the usual quark-gluon plasma which is often considered to reflect “deconfinement” in some way. This paper explores the behavior of these regimes of QCD as the number of colors in the theory, \(N_c\), gets large. In the large \(N_c\) limit the theory is center-symmetric and notions of confinement and deconfinement are unambiguous. The energy density is \(\mathcal{O}(N_c^0)\) in the meson gas, \({{\mathcal {O}}}(N_c^1)\) in the intermediate regime and \({{\mathcal {O}}}(N_c^2)\) in the quark-gluon plasma regime. In the large \(N_c\) limit these regimes may become distinct phases separated by first order phase transitions. The intermediate phase has the peculiar feature that glueballs should exist and have properties that are unchanged from what is seen in the vacuum (up to \(1/N_c \) corrections), while the ordinary dilute gas of mesons with broken chiral symmetry disappears and approximate chiral spin symmetry should emerge.

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$$\mu_B=0$$ 时的大 $$N_c$ QCD 相图
晶格研究表明,在重子化学势为零和温度不断升高的情况下,QCD存在三种特征体制,它们通过平滑的分析交叉连接在一起:在 \(T < T_{ch}\sim 155\) MeV时的强子气体体制,在 \(T_{ch}< T < \sim 3 T_{ch}\) 时的中间体制,称为弦流体,以及在更高温度下的夸克-胶子等离子体体制。这些机制被解释为反映了不同的近似对称性和有效自由度。在强子气体中,有效自由度是强子,QCD 的近似手性对称性被自发打破。中间体系被解释为缺乏自发的手性对称性破缺,同时出现了新的近似对称性--手性自旋对称性,它不是狄拉克拉格朗日的对称性,而是 QCD 拉格朗日约束部分的对称性。而高温体系是通常的夸克-胶子等离子体,通常被认为以某种方式反映了 "去约束"。本文探讨了当理论中的颜色数(\(N_c\))变大时 QCD 的这些制度的行为。在大\(N_c\)极限下,理论是中心对称的,约束和去约束的概念是明确的。在介子气体中,能量密度是\({\mathcal{O}}(N_c^0)\);在中间体系中,能量密度是\({\mathcal{O}}(N_c^1)\);在夸克胶子等离子体体系中,能量密度是\({\mathcal{O}}(N_c^2)\)。在大\(N_c\)极限下,这些制度可能会成为不同的阶段,被一阶相变分隔开来。中间阶段有一个奇特的特征,即胶球应该存在,并且其性质与真空中看到的没有变化(达到 \(1/N_c\) 修正),而具有破损手性对称性的介子的普通稀释气体消失了,近似手性自旋对称性应该出现。
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来源期刊
The European Physical Journal A
The European Physical Journal A 物理-物理:核物理
CiteScore
5.00
自引率
18.50%
发文量
216
审稿时长
3-8 weeks
期刊介绍: Hadron Physics Hadron Structure Hadron Spectroscopy Hadronic and Electroweak Interactions of Hadrons Nonperturbative Approaches to QCD Phenomenological Approaches to Hadron Physics Nuclear and Quark Matter Heavy-Ion Collisions Phase Diagram of the Strong Interaction Hard Probes Quark-Gluon Plasma and Hadronic Matter Relativistic Transport and Hydrodynamics Compact Stars Nuclear Physics Nuclear Structure and Reactions Few-Body Systems Radioactive Beams Electroweak Interactions Nuclear Astrophysics Article Categories Letters (Open Access) Regular Articles New Tools and Techniques Reviews.
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