On the origin of inflation by using exotic smoothness

TL;DR

This paper proposes a geometric inflation model based on exotic smoothness structures in spacetime, leading to a finite-time accelerated expansion driven by topology change, with implications for quantum fluctuations and reheating.

Contribution

It introduces a novel inflation mechanism using exotic smoothness and topology change, differing from traditional scalar field models.

Findings

Achieves more than 60 e-folds of expansion.

Describes inflation as a finite-time topology change.

Provides a geometric interpretation of quantum fluctuations.

Abstract

In this paper we discuss a spacetime having the topology of S^3 x R but with a different smoothness structure leading to a geometric model for inflation, called geometric inflation. In particular this spacetime is not globally hyperbolic and we obtain a time line with a spatial topology change from the 3-sphere to a homology 3-sphere and back. The topology of the spacetime remains invariant. Among the infinite possible smoothness structures of this spacetime, we choose a homology 3-sphere constructed from the knot 8_{10} with hyperbolic geometry, i.e. admitting a homogenous metric of negative scalar curvature. We discuss the accelerated expansion for FLRW cosmology caused by the topology change. In contrast to other inflation models, this process stops after a finite time. Alternatively, the topology change can be also described by a SU(2)-valued scalar field. Then we calculate the expansion rate (having more than 60 e-folds) and the energy time scale. The coupling to matter is also interpreted geometrically and the reheating process (as well the supercooled expansion during inflation) is naturally obtained. The model depends only on a single parameter, a topological invariant of the homology 3-sphere, and assumes a Planck size universe of S^3-topology. The dependence of the model on the initial state and the a geometric interpretation of quantum fluctuations are also discussed.