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arxiv 1408.3393 v2 pith:LIAW2R7Y submitted 2014-08-14 hep-th

N = 4 Super-Yang-Mills on Conic Space as Hologram of STU Topological Black Hole

classification hep-th
keywords blackconiclimitsuper-yang-millstheoriestopologicalbackgroundfields
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We construct four-dimensional N=4 super-Yang-Mills theories on a conic sphere with various background R-symmetry gauge fields. We study free energy and supersymmetric Renyi entropy using heat kernel method as well as localization technique. We find that the universal contribution to the partition function in the free field limit is the same as that in the strong coupling limit, which implies that it may be protected by supersymmetry. Based on the fact that, the conic sphere can be conformally mapped to $S^1\times H^3$ and the R-symmetry background fields can be supported by the R-charges of black hole, we propose that the holographic dual of these theories are five-dimensional, supersymmetric STU topological black holes. We demonstrate perfect agreement between N=4 super-Yang-Mills theories in the planar limit and the STU topological black holes.

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  1. From Weyl Anomaly to Defect Supersymmetric R\'enyi Entropy and Casimir Energy

    hep-th 2025-01 unverdicted novelty 5.0

    In 6D (2,0) theories, defect supersymmetric Rényi entropy contribution is linear in 1/n and equals a constant times (2b - d2); Casimir energy contribution equals -d2 (up to constant) in the chiral algebra limit.