Asymptotic Safety and Canonical Quantum Gravity

TL;DR

This paper explores the connection between Asymptotic Safety and Canonical Quantum Gravity, proposing a framework that combines Hamiltonian formalism with non-perturbative renormalization to develop a consistent, gauge-invariant quantum gravity theory.

Contribution

It introduces a systematic approach linking canonical and covariant quantum gravity via functional renormalization, enabling gauge-invariant observable construction.

Findings

Established a relation between quantization and renormalization group methods.

Developed a framework for defining physical observables in quantum gravity.

Connected the ultraviolet and infrared regimes through non-perturbative flow analysis.

Abstract

In the context of gravity the Lagrangian and Hamiltonian formalisms have been developed largely independently, emphasizing renormalization and quantization, respectively. The formalisms use a different methodology to distinguish between gauge and physical degrees of freedom. In this review we analyze the connection between the Asymptotically Safe and Canonical Quantum Gravity approaches. Based on the Hamiltonian formulation, the Canonical Quantum Gravity approach inherently provides a natural framework for defining observables. This serves as the foundation for constructing the generating functional of the $n$-point correlation functions of physical degrees of freedom. By means of background-independent, non-perturbative renormalization methods well-established in the Lagrangian framework and typically employed in Asymptotic Safety, the resulting generating functional can be handled. In particular, we employ the Functional Renormalization Group to regularize the path integral and to compute the flow connecting the bare theory in the ultraviolet with the effective infrared theory. An important advantage of this approach is that it establishes an explicit, systematic relation between the quantization procedure and the systematics of quantum field theory-based renormalization group methods. More importantly, this synthesis not only bridges canonical and covariant approaches but also paves the way for a consistent and predictive quantum theory of gravity grounded in physically meaningful, gauge-invariant observables.