Hot QCD phase diagram from holographic Einstein–Maxwell–Dilaton models

IF 14.5 2区 物理与天体物理 Q1 PHYSICS, NUCLEAR
Romulo Rougemont , Joaquin Grefa , Mauricio Hippert , Jorge Noronha , Jacquelyn Noronha-Hostler , Israel Portillo , Claudia Ratti
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引用次数: 0

Abstract

In this review, we provide an up-to-date account of quantitative bottom-up holographic descriptions of the strongly coupled quark–gluon plasma (QGP) produced in relativistic heavy-ion collisions, based on the class of gauge-gravity Einstein–Maxwell–Dilaton (EMD) effective models. The holographic approach is employed to tentatively map the QCD phase diagram at finite temperature onto a dual theory of charged, asymptotically Anti-de Sitter (AdS) black holes living in five dimensions. With a quantitative focus on the hot QCD phase diagram, the nonconformal holographic EMD models reviewed here are adjusted to describe first-principles lattice results for the finite-temperature QCD equation of state, with 2+1 flavors and physical quark masses, at zero chemical potential and vanishing electromagnetic fields. We review the evolution of such effective models and the corresponding improvements produced in quantitative holographic descriptions of the deconfined hot QGP phase of QCD. The predictive power of holographic EMD models is tested by quantitatively comparing their predictions for the hot QCD equation of state at nonzero baryon density and the corresponding state-of-the-art lattice QCD results. Hydrodynamic transport coefficients such as the shear and bulk viscosities predicted by these EMD constructions are also compared to the corresponding profiles favored by the latest phenomenological multistage models simultaneously describing different types of heavy-ion data. We briefly report preliminary results from a Bayesian analysis using EMD models, which provide systematic evidence that lattice QCD results at finite temperature and zero baryon density strongly constrains the free parameters of such bottom-up holographic constructions. Remarkably, the set of parameters constrained by lattice results at vanishing chemical potential turns out to produce EMD models in quantitative agreement with lattice QCD results also at finite baryon density. We also review results for equilibrium and transport properties from magnetic EMD models, which effectively describe the hot and magnetized QGP at finite temperatures and magnetic fields with zero chemical potentials. Finally, we provide a critical assessment of the main limitations and drawbacks of the holographic models reviewed in the present work, and point out some perspectives we believe are of fundamental importance for future developments.

全息爱因斯坦-麦克斯韦-膨胀模型的热QCD相图
在这篇综述中,我们提供了一个最新的定量自底向上的全息描述在相对论重离子碰撞中产生的强耦合夸克-胶子等离子体(QGP),基于一类标准重力爱因斯坦-麦克斯韦- dilaton (EMD)有效模型。利用全息方法将有限温度下的QCD相图初步映射到五维带电、渐近反德西特(AdS)黑洞的对偶理论上。为了定量地关注热QCD相图,本文对非共形全息EMD模型进行了调整,以描述有限温度QCD状态方程的第一性原理晶格结果,该方程具有2+1香味和物理夸克质量,化学势为零,电磁场消失。我们回顾了这些有效模型的演变和相应的改进产生了定量全息描述的定义热QGP相的QCD。通过定量比较全息EMD模型对非零重子密度下热QCD状态方程的预测和相应的最新晶格QCD结果,验证了全息EMD模型的预测能力。这些EMD结构预测的流体动力输运系数,如剪切和体粘度,也与最新的现象多阶段模型所支持的相应剖面进行了比较,同时描述了不同类型的重离子数据。我们简要报告了使用EMD模型的贝叶斯分析的初步结果,该结果提供了系统的证据,证明晶格QCD在有限温度和零重子密度下的结果强烈限制了这种自下而上全息结构的自由参数。值得注意的是,在化学势消失时,晶格结果约束的参数集产生的EMD模型在数量上与有限重子密度下的晶格QCD结果一致。我们还回顾了磁性EMD模型的平衡和输运性质的结果,这些模型有效地描述了有限温度和零化学势磁场下的热和磁化QGP。最后,我们对目前工作中回顾的全息模型的主要局限性和缺点进行了批判性评估,并指出了我们认为对未来发展至关重要的一些观点。
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来源期刊
Progress in Particle and Nuclear Physics
Progress in Particle and Nuclear Physics 物理-物理:核物理
CiteScore
24.50
自引率
3.10%
发文量
41
审稿时长
72 days
期刊介绍: Taking the format of four issues per year, the journal Progress in Particle and Nuclear Physics aims to discuss new developments in the field at a level suitable for the general nuclear and particle physicist and, in greater technical depth, to explore the most important advances in these areas. Most of the articles will be in one of the fields of nuclear physics, hadron physics, heavy ion physics, particle physics, as well as astrophysics and cosmology. A particular effort is made to treat topics of an interface type for which both particle and nuclear physics are important. Related topics such as detector physics, accelerator physics or the application of nuclear physics in the medical and archaeological fields will also be treated from time to time.
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