AdS/CFT Correspondence in Hyperbolic Lattices

Abstract

The AdS/CFT correspondence, also known as the gravity/gauge duality, posits a dual relationship between the theory of gravity in Anti-de Sitter (AdS) space and conformal field theory (CFT) defined on its lower-dimensional boundary. This correspondence provides a means of mapping problems from one theory to the other, offering insights into quantum gravity and quantum field theory. Despite its importance in contemporary physics, the AdS/CFT correspondence remains a conjecture, and further experimental investigation is highly sought after. Here, we experimentally explore the AdS/CFT correspondence in both conventional type-I and previously overlooked type-II hyperbolic lattices, as the discretized regularizations of spatial geometries of pure AdS2+1 spacetime and AdS2+1 black hole. Using time-resolved and pump-prob measurements, we identify distinct geodesic behaviors in the absence or presence of an analogue black hole. Moreover, we experimentally confirm two pivotal theoretical predictions of the AdS/CFT correspondence: the Ryu-Takayanagi (RT) formula that characterizes the entanglement entropy of the boundary CFT2 through the minimal geodesic in the spatial section of bulk AdS2+1, and the exponential dependence of the boundary-boundary two-point correlation function on the hyperbolic distance which determines the conformal dimension of the boundary CFT1 associated with the scalar field mass in the bulk Euclidean AdS2 (EAdS2). This initial experimental effort opens a new avenue for future investigation on the gravity/gauge duality and the exploration of quantum-gravity-inspired phenomena in classical systems