English

Geometric Surprises in the Python's Lunch Conjecture

High Energy Physics - Theory 2024-06-12 v2

Abstract

A bulge surface, on a time reflection-symmetric Cauchy slice of a holographic spacetime, is a non-minimal extremal surface that occurs between two locally minimal surfaces homologous to a given boundary region. According to the python's lunch conjecture of Brown et al., the bulge's area controls the complexity of bulk reconstruction, in the sense of the amount of post-selection that needs to be overcome for the reconstruction of the entanglement wedge beyond the outermost extremal surface. We study the geometry of bulges in a variety of classical spacetimes, and discover a number of surprising features that distinguish them from more familiar extremal surfaces such as Ryu-Takayanagi surfaces: they spontaneously break spatial isometries, both continuous and discrete; they are sensitive to the choice of boundary infrared regulator; they can self-intersect; and they probe entanglement shadows, orbifold singularities, and compact spaces such as the sphere in AdSp×Sq_p\times S^q. These features imply, according to the python's lunch conjecture, novel qualitative differences between complexity and entanglement in the holographic context. We also find, surprisingly, that extended black brane interiors have a non-extensive complexity; similarly, for multi-boundary wormhole states, the complexity pleateaus after a certain number of boundaries have been included.

Keywords

Cite

@article{arxiv.2401.06678,
  title  = {Geometric Surprises in the Python's Lunch Conjecture},
  author = {Gurbir Arora and Matthew Headrick and Albion Lawrence and Martin Sasieta and Connor Wolfe},
  journal= {arXiv preprint arXiv:2401.06678},
  year   = {2024}
}

Comments

Examples added and exposition improved; 62 pages

R2 v1 2026-06-28T14:15:25.065Z