Quantum Information Approaches to Quantum Gravity

TL;DR

This thesis applies quantum information theory to explore quantum gravity via AdS/CFT, refining dualities and analyzing entanglement dynamics in quantum systems to deepen understanding of gravitational emergence from quantum correlations.

Contribution

It introduces refined dualities between OPE blocks and geodesic fields in less symmetric states and develops new tools to analyze entanglement measures and their dynamics.

Findings

Refined duality between OPE blocks and geodesic fields in excited states.

Analytic expressions for derivatives of negativity and entanglement measures.

Bounds on the rate of entanglement growth and state distinguishability.

Abstract

In this thesis we apply techniques from quantum information theory to study quantum gravity within the framework of the anti-de Sitter / conformal field theory correspondence (AdS/CFT). Through AdS/CFT, progress has been made in understanding the structure of entanglement in quantum field theories, and in how gravitational physics can emerge from these structures. However, this understanding is far from complete and will require the development of new tools to quantify correlations in CFT. This thesis presents refinements of a duality between operator product expansion (OPE) blocks in the CFT, giving the contribution of a conformal family to the OPE, and geodesic integrated fields in AdS which are diffeomorphism invariant quantities. This duality was originally discovered in the maximally symmetric setting of pure AdS dual to the CFT ground state. In less symmetric states the duality must be modified. Working with excited states within AdS$_3$/CFT$_2$, this thesis shows how the OPE block decomposes into more fine-grained CFT observables that are dual to AdS fields integrated over non-minimal geodesics. Additionally, this thesis contains results on the dynamics of entanglement measures for general quantum systems. Results are presented for the family of quantum R\'enyi entropies and entanglement negativity. R\'enyi entropies are studied for general dynamics by imposing special initial conditions. Around pure, separable initial states, all R\'enyi entropies grow with the same timescale at leading, and next-to-leading order. Mathematical tools are developed for the differentiation of non-analytic matrix functions with respect to constrained arguments and are used to construct analytic expressions for derivatives of negativity. We establish bounds on the rate of change of state distinguishability and the rate of entanglement growth for closed systems. Note: Abstract shortened.