The nonlinear future stability of the FLRW family of solutions to the irrotational Euler–Einstein system with a positive cosmological constant

Author(s)

Rodnianski, Igor; Speck, Jared R.

Abstract

In this article, we study small perturbations of the family of Friedmann-Lemaître-Robertson-Walker cosmological background solutions to the coupled Euler-Einstein system with a positive cosmological constant in 1+3 spacetime dimensions. The background solutions model an initially uniform quiet fluid of positive energy density evolving in a spacetime undergoing exponentially accelerated expansion. Our nonlinear analysis shows that under the equation of state p=c[superscript 2]ρ,0 < c[superscript 2] < 1/3, the background metric + fluid solutions are globally future-stable under small irrotational perturbations of their initial data. In particular, we prove that the perturbed spacetime solutions, which have the topological structure [0,∞)XT[superscript 3], are future causally geodesically complete. Our analysis is based on a combination of energy estimates and pointwise decay estimates for quasilinear wave equations featuring dissipative inhomogeneous terms. Our main new contribution is showing that when 0 < c[superscript 2] < 1/3, exponential spacetime expansion is strong enough to suppress the formation of fluid shocks. This contrasts against a well-known result of Christodoulou, who showed that in Minkowski spacetime, the corresponding constant-state irrotational fluid solutions are unstable.

Date issued

2013

URI

http://hdl.handle.net/1721.1/96729

Department

Massachusetts Institute of Technology. Department of Mathematics

Journal

Journal of the European Mathematical Society

Publisher

European Mathematical Society Publishing House

Citation

Rodnianski, Igor, and Jared Speck. “The Nonlinear Future Stability of the FLRW Family of Solutions to the Irrotational Euler–Einstein System with a Positive Cosmological Constant.” J. Eur. Math. Soc. 15, no. 6 (2013): 2369–2462.

Version: Author's final manuscript

ISSN

1435-9855