English

Holograms In Our World

High Energy Physics - Theory 2023-09-07 v2 General Relativity and Quantum Cosmology Quantum Physics

Abstract

In AdS/CFT, the entanglement wedge EW(B)(B) is the portion of the bulk geometry that can be reconstructed from a boundary region BB; in other words, EW(B)(B) is the hologram of BB. We extend this notion to arbitrary spacetimes. Given any gravitating region aa, we define a max- and a min-entanglement wedge, emax(a)e_{\rm max}(a) and emin(a)e_{\rm min}(a), such that emin(a)emax(a)ae_{\rm min}(a)\supset e_{\rm max}(a)\supset a. Unlike their analogues in AdS/CFT, these two spacetime regions can differ already at the classical level, when the generalized entropy is approximated by the area. All information outside aa in emax(a)e_{\rm max}(a) can flow inwards towards aa, through quantum channels whose capacity is controlled by the areas of intermediate homology surfaces. In contrast, all information outside emin(a)e_{\rm min}(a) can flow outwards. The generalized entropies of appropriate entanglement wedges obey strong subadditivity, suggesting that they represent the von Neumann entropies of ordinary quantum systems. The entanglement wedges of suitably independent regions satisfy a no-cloning relation. This suggests that it may be possible for an observer in aa to summon information from spacelike related points in emax(a)e_{\rm max}(a), using resources that transcend the semiclassical description of aa.

Keywords

Cite

@article{arxiv.2302.07892,
  title  = {Holograms In Our World},
  author = {Raphael Bousso and Geoff Penington},
  journal= {arXiv preprint arXiv:2302.07892},
  year   = {2023}
}

Comments

26 pages, 5 figures. v2: minor fixes

R2 v1 2026-06-28T08:41:06.312Z