Quantum-Deformed Phase-Space Geometry and Emergent Inflation in Effective Four-Dimensional Spacetime

TL;DR

This paper develops a phase-space approach to quantum-deformed gravity, deriving an effective four-dimensional inflationary model that incorporates quantum gravity effects as geometric deformations influencing cosmic inflation.

Contribution

It introduces a novel quantum-deformed phase-space framework that leads to an effective inflationary cosmology with quantum gravity corrections embedded in the geometry.

Findings

Quantum-deformed phase-space induces anisotropic Hamilton geometry.

Effective spacetime metric reduces to a conformally deformed FLRW geometry.

Inflationary dynamics and perturbations are influenced by phase-space deformation.

Abstract

A phase-space approach to quantum-deformed gravity is developed. Following its reduction to an effective four-dimensional spacetime structure, we utilize it in reanalyzing the cosmic inflationary dynamics and quantum gravity. The construction starts on cotangent bundle, where the gravitational Hamiltonian is deformed by a zero-homogeneous scalar determined by projective momentum directions and quantum phase-space properties. This induces an anisotropic Hamilton geometry on a non-null conic domain, from which an effective spacetime metric is obtained through a section-pullback procedure. In the homogeneous and isotropic sector, the pullback consistently reduces to a conformally deformed FLRW geometry governed by a scalar deformation field. We derive the corresponding modified Einstein, Klein-Gordon, geodesic-deviation, and Raychaudhuri equations. This allows for the construction of inflationary background dynamics, slow-roll regime, number of e-folds, as well as scalar and tensor perturbations. The resulting framework shows that leading inflationary corrections arise from the phase-space deformation and its time dependence, while the canonical quantization of cosmological perturbations remains standard after suitable background redefinitions. In this way, the model provides a covariant and controlled link between quantum-deformed phase-space geometry and effective four-dimensional inflationary dynamics. The present construction shows that effects of quantum gravity can be consistently encoded as a deformation of projective phase-space geometry, from which an effective spacetime metric emerges only after a section-dependent reduction.