Towards the graviton from spinfoams: higher order corrections in the 3d toy model

TL;DR

This paper investigates higher-order corrections to the graviton propagator within a 3d spinfoam model, revealing significant quantum geometric contributions that could alter traditional perturbative approaches in quantum gravity.

Contribution

It explicitly computes next-to-leading and next-to-next-to-leading order corrections in a 3d toy model, highlighting the impact of non-Regge quantum geometry on graviton amplitudes.

Findings

Next-to-leading order arises from Regge action expansion.

Next-to-next-to-leading order includes non-Regge quantum geometry effects.

Higher-order corrections can significantly modify perturbative expansions.

Abstract

We consider the recent calculation gr-qc/0508124 of the graviton propagator in the spinfoam formalism. Within the 3d toy model introduced in gr-qc/0512102, we test how the spinfoam formalism can be used to construct the perturbative expansion of graviton amplitudes. Although the 3d graviton is a pure gauge, one can choose to work in a gauge where it is not zero and thus reproduce the structure of the 4d perturbative calculations. We compute explicitly the next to leading and next to next to leading orders, corresponding to one-loop and two-loop corrections. We show that while the first arises entirely from the expansion of the Regge action around the flat background, the latter receives contributions from the microscopic, non Regge-like, quantum geometry. Surprisingly, this new contribution reduces the magnitude of the next to next to leading order. It thus appears that the spinfoam formalism is likely to substantially modify the conventional perturbative expansion at higher orders. This result supports the interest in this approach. We then address a number of open issues in the rest of the paper. First, we discuss the boundary state ansatz, which is a key ingredient in the whole construction. We propose a way to enhance the ansatz in order to make the edge lengths and dihedral angles conjugate variables in a mathematically well-defined way. Second, we show that the leading order is stable against different choices of the face weights of the spinfoam model; the next to leading order, on the other hand, is changed in a simple way, and we show that the topological face weight minimizes it. Finally, we extend the leading order result to the case of a regular, but not equilateral, tetrahedron.