Einstein-dilaton-four-Maxwell Holographic Anisotropic Models

arXiv - PHYS - High Energy Physics - Theory Pub Date : 2024-09-18 DOI:arxiv-2409.12131

Irina Ya. Aref'eva, Kristina Rannu, Pavel Slepov

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Abstract

In recent literature on holographic QCD, the consideration of the five-dimensional Einstein-dilaton-Maxwell models has played a crucial role. Typically, one Maxwell field is associated with the chemical potential, while additional Maxwell fields are used to describe the anisotropy of the model. A more general scenario involves up to four Maxwell fields. The second field represents spatial longitudinal-transverse anisotropy, while the third and fourth fields describe anisotropy induced by an external magnetic field. We consider an ansatz for the metric characterized by four functions at zero temperature and five functions at non-zero temperature. Maxwell field related to the chemical potential is treated with the electric ansatz, as is customary, whereas the remaining three Maxwell fields are treated with a magnetic ansatz. We demonstrate that for the fully anisotropic diagonal metric only six out of the seven equations are independent. One of the matter equations -- either the dilaton or the vector potential equation -- follows from the Einstein equations and the remaining matter equation. This redundancy arises due to the Bianchi identity for the Einstein tensor and the specific form of the stress-energy tensor in the model. A procedure for solving this system of six equations is provided. This method generalizes previously studied cases involving up to three Maxwell fields. In the solution with three magnetic fields our analysis shows, that the dilaton equation is a consequence of the five Einstein equations and the equation for the vector potential

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爱因斯坦-二拉顿-四麦克斯韦全息各向异性模型

在最近关于全息QCD的文献中，对五维爱因斯坦-二拉顿-麦克斯韦模型的考虑起到了至关重要的作用。通常，一个麦克斯韦场与化学势相关联，而额外的麦克斯韦场则用于描述模型的各向异性。更普遍的情况是涉及多达四个麦克斯韦场。第二个场代表空间纵横各向异性，而第三个和第四个场则描述由外部磁场引起的各向异性。我们考虑了一个公设解析模型，其特点是零温时有四个函数，非零温时有五个函数。我们证明，对于完全各向异性对角度量，七个方程中只有六个是独立的。其中一个物质方程--迭拉顿方程或矢量势方程--来自爱因斯坦方程和其余物质方程。这种冗余是由于爱因斯坦张量的比安奇同一性和模型中应力能量张量的特殊形式造成的。本文提供了求解这个六方程系统的程序。这种方法推广了以前研究过的最多涉及三个麦克斯韦场的情况。在涉及三个磁场的求解中，我们的分析表明，稀拉顿方程是五个爱因斯坦方程和矢量势方程的结果。

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arXiv - PHYS - High Energy Physics - Theory

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