Vacuum Condensate Picture of Quantum Gravity

TL;DR

This paper explores a nonperturbative approach to quantum gravity using lattice path integrals, revealing a gravitational vacuum condensate and scaling behaviors that could lead to observable deviations from classical gravity at large scales.

Contribution

It introduces a new phase in quantum gravity characterized by a vacuum condensate and scaling exponents, providing a nonperturbative framework analogous to QCD.

Findings

Existence of a gravitational vacuum condensate.

Scaling exponents for G and correlation functions.

Potential deviations from classical gravity at large scales.

Abstract

In quantum gravity perturbation theory in Newton's constant G is known to be badly divergent, and as a result not very useful. Nevertheless some of the most interesting phenomena in physics are often associated with non-analytic behavior in the coupling constant and the existence of nontrivial quantum condensates. It is therefore possible that pathologies encountered in the case of gravity are more likely the result of inadequate analytical treatment, and not necessarily a reflection of some intrinsic insurmountable problem. The nonperturbative treatment of quantum gravity via the Regge-Wheeler lattice path integral formulation reveals the existence of a new phase involving a nontrivial gravitational vacuum condensate, and a new set of scaling exponents characterizing both the running of G and the long-distance behavior of invariant correlation functions. The appearance of such a gravitational condensate is viewed as analogous to the (equally nonperturbative) gluon and chiral condensates known to describe the physical vacuum of QCD. The resulting quantum theory of gravity is highly constrained, and its physical predictions are found to depend only on one adjustable parameter, a genuinely nonperturbative scale xi in many ways analogous to the scaling violation parameter Lambda MSbar of QCD. Recent results point to significant deviations from classical gravity on distance scales approaching the effective infrared cutoff set by the observed cosmological constant. Such subtle quantum effects are expected to be initially small on current cosmological scales, but could become detectable in future high precision satellite experiments.