Abstract
Introduction of electric field in the D-brane worldvolume induces a horizon in the open string geometry perceived by the brane fluctuations. We study the holographic entanglement entropy (HEE) and subregion complexity (HSC) in these asymptotically AdS geometries in three, four and five dimensions aiming to capture these quantities in the flavor sector introduced by the D-branes. Both the strip and spherical subregions have been considered. We show that the Bekenstein-Hawking entropy associated with the open string horizon, which earlier failed to reproduce the thermal entropy in the boundary, now precisely matches with the entanglement entropy at high temperatures. We check the validity of embedding function theorem while computing the HEE and attempt to reproduce the first law of entanglement thermodynamics, at least at leading order. On the basis of obtained results, we also reflect upon consequences of applying Ryu-Takayanagi proposal on these non-Einstein geometries.
Highlights
Introduction of electric field in the D-brane worldvolume induces a horizon in the open string geometry perceived by the brane fluctuations
We study the holographic entanglement entropy (HEE) and subregion complexity (HSC) in these asymptotically AdS geometries in three, four and five dimensions aiming to capture these quantities in the flavor sector introduced by the D-branes
We show that the Bekenstein-Hawking entropy associated with the open string horizon, which earlier failed to reproduce the thermal entropy in the boundary, precisely matches with the entanglement entropy at high temperatures
Summary
Let us first review the emergence of open string geometries in our context. The introduction of Nf number of Dp-branes in the limit Nc2 → ∞, NcNf → ∞, Nf /Nc 1 leads to conjecturing a new duality between gravity in open string geometries and the physics of the flavors in the dual gauge theory. This duality has been exploited to study thermodynamics of the flavor fields [36], chaos in the flavor sector [70] and in numerous other contexts. These exercises are expected to capture the robustness of RT proposal to violation of energy conditions and to explore their compatibility with non-Einstein solutions
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