Localized past stability of the subcritical Kasner-scalar field spacetimes

Abstract

We prove the nonlinear stability, in the contracting direction, of the entire subcritical family of Kasner-scalar field solutions to the Einstein-scalar field equations in four spacetime dimensions. Our proof relies on a zero-shift, orthonormal frame decomposition of a conformal representation of the Einstein-scalar field equations. To synchronise the big bang singularity, we use the time coordinate τ = (23φ), where φ is the scalar field, which coincides with a conformal harmonic time slicing. We show that the perturbed solutions are asymptotically pointwise Kasner, geodesically incomplete to the past and terminate at quiescent, crushing big bang singularities located at τ=0, which are characterised by curvature blow up. Specifically, we establish two stability theorems. The first is a global in-space stability result where the perturbed spacetimes are of the form M =t∈ (0,t0] τ-1(\t\) (0,t0] × T3. The second is a localised version where the perturbed spacetimes are given by M=t∈ (0,t0]τ-1(\t\) t∈ (0,t0] \t\×B(t) with time-dependent radius function (t)=0+(1-)0((tt0)1-ε-1). Spatial localisation is achieved through our choice of zero-shift, harmonic time slicing that leads to hyperbolic evolution equations with a finite propagation speed.

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