Table of Contents
Fetching ...

Localized big bang stability for the Einstein-scalar field equations

Florian Beyer, Todd A. Oliynyk

Abstract

We prove the nonlinear stability in the contracting direction of Friedmann-Lemaître-Robertson-Walker (FLRW) solutions to the Einstein-scalar field equations in $n\geq 3$ spacetime dimensions that are defined on spacetime manifolds of the form $(0,t_0]\times \mathbb{T}^{n-1}$, $t_0>0$. Stability is established under the assumption that the initial data is \textit{synchronized}, which means that on the initial hypersurface $Σ= \{t_0\}\times \mathbb{T}^{n-1}$ the scalar field $τ= \exp\bigl(\sqrt{\frac{2(n-2)}{n-1}}φ\bigr) $ is constant, that is, $Σ=τ^{-1}(\{t_0\})$. As we show that all initial data sets that are sufficiently close to FRLW ones can be evolved via the Einstein-scalar field equation into new initial data sets that are \textit{synchronized}, no generality is lost by this assumption. By using $τ$ as a time coordinate, we establish that the perturbed FLRW spacetime manifolds are of the form $M = \bigcup_{t\in (0,t_0]}τ^{-1}(\{t\})\cong (0,t_0]\times \mathbb{T}^{n-1}$, the perturbed FLRW solutions are asymptotically pointwise Kasner as $τ\searrow 0$, and a big bang singularity, characterised by the blow up of the scalar curvature, occurs at $τ=0$. An important aspect of our past stability proof is that we use a hyperbolic gauge reduction of the Einstein-scalar field equations. As a consequence, all of the estimates used in the stability proof can be localized and we employ this property to establish a corresponding localized past stability result for the FLRW solutions.

Localized big bang stability for the Einstein-scalar field equations

Abstract

We prove the nonlinear stability in the contracting direction of Friedmann-Lemaître-Robertson-Walker (FLRW) solutions to the Einstein-scalar field equations in spacetime dimensions that are defined on spacetime manifolds of the form , . Stability is established under the assumption that the initial data is \textit{synchronized}, which means that on the initial hypersurface the scalar field is constant, that is, . As we show that all initial data sets that are sufficiently close to FRLW ones can be evolved via the Einstein-scalar field equation into new initial data sets that are \textit{synchronized}, no generality is lost by this assumption. By using as a time coordinate, we establish that the perturbed FLRW spacetime manifolds are of the form , the perturbed FLRW solutions are asymptotically pointwise Kasner as , and a big bang singularity, characterised by the blow up of the scalar curvature, occurs at . An important aspect of our past stability proof is that we use a hyperbolic gauge reduction of the Einstein-scalar field equations. As a consequence, all of the estimates used in the stability proof can be localized and we employ this property to establish a corresponding localized past stability result for the FLRW solutions.
Paper Structure (53 sections, 20 theorems, 518 equations)

This paper contains 53 sections, 20 theorems, 518 equations.

Key Result

Theorem 1.2

Solutions $\{g_{ij},\tau\}$ of the conformal Einstein-scalar field equations that are generated from sufficiently differentiable, synchronized initial data imposed on $\{t_0\}\times \mathbb{T}{}^{n-1}$ that is suitably close to the FLRW data exist on the spacetime region $M \cong \bigcup_{t\in (0,t_

Theorems & Definitions (46)

  • Definition 1.1
  • Theorem 1.2: Past global stability of the FLRW solution of the Einstein-scalar field equations
  • Theorem 1.3: Localized past stability of the FLRW solution of the Einstein-scalar field system
  • Remark 4.1
  • Remark 5.1
  • Proposition 5.2
  • proof
  • Remark 5.3
  • Remark 5.4
  • Remark 5.5
  • ...and 36 more