Near-extremal fluid mechanics

Using the framework of higher-form global symmetries, we examine the regime of validity of force-free electrodynamics by evaluating the lifetime of the electric field operator, which is non-conserved due to screening effects. We focus on a holographic model which has the same global symmetry as that of low energy plasma and obtain the lifetime of (non-conserved) electric flux in a strong magnetic field regime. The lifetime is inversely correlated to the magnetic field strength and thus suppressed in the strong field regime.

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“…Similar computation for the holographic theory dual to a system with ordinary(zero-form) U(1) symmetry can be found in e.g [40,41]…”

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confidence: 52%

Operator lifetime and the force-free electrodynamic limit of magnetised holographic plasma

Poovuttikul

Rajagopal

2021

J. High Energ. Phys.

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“…In this limit, the outer and the inner horizons come close to each other and can lead to the pinching of the holographic radial contour. It would be interesting to see how this should be dealt with and make contact with the derivative expansion in near-extremal branes recently claimed in [44].…”

Section: Jhep03(2021)233mentioning

confidence: 99%

Holographic KMS relations at finite density

Loganayagam

Ray

Sharma

et al. 2021

J. High Energ. Phys.

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We extend the holographic Schwinger-Keldysh prescription introduced in [1] to charged black branes, with a view towards studying Hawking radiation in these backgrounds. Equivalently we study the real time fluctuations of the dual CFT held at finite temperature and finite chemical potential. We check our prescription using charged Dirac probe fields. We solve the Dirac equation in a boundary derivative expansion extending the results in [2]. The Schwinger-Keldysh correlators derived using this prescription automatically satisfy the appropriate KMS relations with Fermi-Dirac factors.

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“…It will also be quite interesting to extend the holographic path integral contour to near-extremal black holes and make connection with the derivative expansion scheme given in [47] for near-extremal black branes.…”

Section: Jhep08(2021)169mentioning

confidence: 99%

Open effective theory of scalar field in rotating plasma

Chakrabarty

Aswin

2021

J. High Energ. Phys.

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We study the effective dynamics of an open scalar field interacting with a strongly-coupled two-dimensional rotating CFT plasma. The effective theory is determined by the real-time correlation functions of the thermal plasma. We employ holographic Schwinger-Keldysh path integral techniques to compute the effective theory. The quadratic effective theory computed using holography leads to the linear Langevin dynamics with rotation. The noise and dissipation terms in this equation get related by the fluctuation-dissipation relation in presence of chemical potential due to angular momentum. We further compute higher order terms in the effective theory of the open scalar field. At quartic order, we explicitly compute the coefficient functions that appear in front of various terms in the effective action in the limit when the background plasma is slowly rotating. The higher order effective theory has a description in terms of the non-linear Langevin equation with non-Gaussianity in the thermal noise.

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Near-extremal fluid mechanics

Cited by 8 publications

References 127 publications

Operator lifetime and the force-free electrodynamic limit of magnetised holographic plasma

Operator lifetime and the force-free electrodynamic limit of magnetised holographic plasma

Holographic KMS relations at finite density

Open effective theory of scalar field in rotating plasma

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