S
Sebastian Grieninger
Researcher at Autonomous University of Madrid
Publications - 30
Citations - 580
Sebastian Grieninger is an academic researcher from Autonomous University of Madrid. The author has contributed to research in topics: Magnetic field & Quantum entanglement. The author has an hindex of 13, co-authored 25 publications receiving 384 citations. Previous affiliations of Sebastian Grieninger include Spanish National Research Council & Vienna University of Technology.
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Zoology of solid \& fluid holography — Goldstone modes and phase relaxation
TL;DR: In this paper, a comprehensive classification of isotropic solid and fluid holographic models with broken translational invariance is provided, where the authors consider the explicit (EXB) and spontaneous (SSB) breaking of translations and emphasize the differences with respect to their solid counterpart.
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Longitudinal Sound and Diffusion in Holographic Massive Gravity
TL;DR: In this article, the authors consider a simple class of holographic massive gravity models for which the dual field theories break translational invariance spontaneously and identify three hydrodynamic modes in this sector: a pair of sound modes and one diffusion mode.
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Holographic quenches and anomalous transport
TL;DR: In this paper, the authors studied the response of the chiral magnetic effect due to continuous quenches induced by time dependent electric fields within holography and derived the amplitudes by solving the (ODE) Laplace transformed equations.
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On the Hydrodynamic Description of Holographic Viscoelastic Models
TL;DR: In this paper, it was shown that the correct dual hydrodynamic description of homogeneous holographic models with spontaneously broken translations must include the so-called strain pressure, a novel transport coefficient proposed recently.
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Magnetophonons & type-B Goldstones from hydrodynamics to holography
TL;DR: In this paper, a detailed analysis of a large class of effective holographic models with broken translations at finite charge density and magnetic field was performed, and the dispersion relations of the hydrodynamic modes at zero magnetic field and successfully match them to the predictions from charged hydrodynamics.