English

Conformal geometry from entanglement

Quantum Physics 2025-03-19 v2 Strongly Correlated Electrons High Energy Physics - Theory

Abstract

In a physical system with conformal symmetry, observables depend on cross-ratios, measures of distance invariant under global conformal transformations (conformal geometry for short). We identify a quantum information-theoretic mechanism by which the conformal geometry emerges at the gapless edge of a 2+1D quantum many-body system with a bulk energy gap. We introduce a novel pair of information-theoretic quantities (ctot,η)(\mathfrak{c}_{\mathrm{tot}}, \eta) that can be defined locally on the edge from the wavefunction of the many-body system, without prior knowledge of any distance measure. We posit that, for a topological groundstate, the quantity ctot\mathfrak{c}_{\mathrm{tot}} is stationary under arbitrary variations of the quantum state, and study the logical consequences. We show that stationarity, modulo an entanglement-based assumption about the bulk, implies (i) ctot\mathfrak{c}_{\mathrm{tot}} is a non-negative constant that can be interpreted as the total central charge of the edge theory. (ii) η\eta is a cross-ratio, obeying the full set of mathematical consistency rules, which further indicates the existence of a distance measure of the edge with global conformal invariance. Thus, the conformal geometry emerges from a simple assumption on groundstate entanglement. We show that stationarity of ctot\mathfrak{c}_{\mathrm{tot}} is equivalent to a vector fixed-point equation involving η\eta, making our assumption locally checkable. We also derive similar results for 1+1D systems under a suitable set of assumptions.

Keywords

Cite

@article{arxiv.2404.03725,
  title  = {Conformal geometry from entanglement},
  author = {Isaac H. Kim and Xiang Li and Ting-Chun Lin and John McGreevy and Bowen Shi},
  journal= {arXiv preprint arXiv:2404.03725},
  year   = {2025}
}

Comments

48+31 pages, 25 figures

R2 v1 2026-06-28T15:44:33.915Z