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Main Authors: Lu, Zhenkang, Ran, Cheng, Wu, Shao-feng
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.12890
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author Lu, Zhenkang
Ran, Cheng
Wu, Shao-feng
author_facet Lu, Zhenkang
Ran, Cheng
Wu, Shao-feng
contents We propose a method to reconstruct the metric and its arbitrary-order derivatives at the horizon for any static, planar-symmetric black hole, using an infinite set of discrete pole-skipping points in momentum space where the boundary Green's function becomes ambiguous. This method is fully analytical and involves solving only linear equations. The near-horizon reconstruction can extend either inside or outside the horizon until reaching the nearest singularity in the complex radial plane. It further enables a reinterpretation of any pure gravitational field equation in pole-skipping data. Moreover, our method reveals that the pole-skipping points are redundant: only a subset is independent, while the rest are fixed by an equal number of homogeneous polynomial constraints. These identities are universal, independent of the details of the bulk geometry, including its dimensionality, asymptotic behavior, or the existence of a holographic duality.
format Preprint
id arxiv_https___arxiv_org_abs_2506_12890
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Bulk Spacetime Encoding via Boundary Ambiguities
Lu, Zhenkang
Ran, Cheng
Wu, Shao-feng
High Energy Physics - Theory
We propose a method to reconstruct the metric and its arbitrary-order derivatives at the horizon for any static, planar-symmetric black hole, using an infinite set of discrete pole-skipping points in momentum space where the boundary Green's function becomes ambiguous. This method is fully analytical and involves solving only linear equations. The near-horizon reconstruction can extend either inside or outside the horizon until reaching the nearest singularity in the complex radial plane. It further enables a reinterpretation of any pure gravitational field equation in pole-skipping data. Moreover, our method reveals that the pole-skipping points are redundant: only a subset is independent, while the rest are fixed by an equal number of homogeneous polynomial constraints. These identities are universal, independent of the details of the bulk geometry, including its dimensionality, asymptotic behavior, or the existence of a holographic duality.
title Bulk Spacetime Encoding via Boundary Ambiguities
topic High Energy Physics - Theory
url https://arxiv.org/abs/2506.12890