Future stability of solutions of the Einstein-nonlinear scalar field system with decelerated expansion

Abstract

We study solutions to the Einstein equations coupled to a nonlinear scalar field with exponential potential. This system admits Friedmann-Lema\itre-Robertson-Walker solutions undergoing decelerated expansion, with T3 spatial topology and scale factor a(t) = tp for 1/3 < p < 1. For each p ∈ (2/3,1), we prove that the corresponding FLRW spacetime is future-stable as a solution to the Einstein-nonlinear scalar field system. Given initial data on a spacelike hypersurface that is sufficiently close to the FLRW data, we show the resulting solution is future-causal geodesically complete, and remains close to the FLRW solution for all time. Moreover, we show the perturbed metric components and scalar field converge to spatially homogeneous functions as t → ∞. A key feature of our analysis is the decomposition of the metric and scalar field perturbations into their spatial averages and oscillatory remainders with zero average.