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Nidal Haddad
Researcher at Bethlehem University
Publications - 13
Citations - 198
Nidal Haddad is an academic researcher from Bethlehem University. The author has contributed to research in topics: Black hole & Black brane. The author has an hindex of 6, co-authored 13 publications receiving 193 citations. Previous affiliations of Nidal Haddad include University of Barcelona.
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Black brane viscosity and the Gregory-Laflamme instability
TL;DR: In this article, the authors studied long wavelength perturbations of neutral black p-branes in asymptotically flat space and showed that solutions of the relativistic hydrodynamic equations for an effective p + 1-dimensional fluid yield solutions to the vacuum Einstein equations in a derivative expansion.
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Self-similar critical geometries at horizon intersections and mergers
TL;DR: In this article, the intersection between a black hole horizon and a cosmological deSitter horizon is studied in the space of higher-dimensional black hole solutions, and the critical geometries that control topology-changing transitions are described.
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Black Brane Viscosity and the Gregory-Laflamme Instability
TL;DR: In this article, the authors studied long wavelength perturbations of neutral black p-branes in asymptotically flat space and showed that solutions of the relativistic hydrodynamic equations for an effective p+1-dimensional fluid yield solutions to the vacuum Einstein equations in a derivative expansion.
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Black strings ending on horizons
TL;DR: In this paper, an approximate static gravitational solution of the Einstein equations, with negative cosmological constant, describing a test black string stretching from the boundary of the Schwarzschild-AdS5 black brane toward the horizon was constructed.
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Hawking radiation from small black holes at strong coupling and large N
TL;DR: In this article, the holographic stress tensor of the Unruh state for weakly coupled Hawking radiation was computed, and it was shown that the expectation value of the stress tensors is finite on both the future and past horizons, and at this order there are no flux terms as is expected in the black droplet phase.