Generic Blow-Up Results for the Wave Equation in the Interior of a Schwarzschild Black Hole

Fournodavlos, Grigorios; Sbierski, Jan

doi:10.1007/s00205-019-01434-0

Cited by 30 publications

(26 citation statements)

References 38 publications

(70 reference statements)

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“…Examples are the Schwarzschild singularity or black hole singularities occurring in spherically symmetric solutions to the Einstein-scalar field model [9], where a logarithmic blow up behaviour has been observed for spatially homogeneous waves. Such logarithmic blow up behaviour was recently confirmed [15] for generic linear waves in the Schwarzschild black hole interior. The aforementioned blow up behaviours, however, are in contrast to the behaviour of waves observed near null boundaries, where linear and dynamical waves have been shown in general to extend continuously past the relevant null hypersurfaces [10], [16]- [22], see also [24].…”

Section: Introduction and Main Theoremssupporting

confidence: 53%

The wave equation near flat Friedmann–Lemaître–Robertson–Walker and Kasner Big Bang singularities

Alho

Fournodavlos

Franzen

2019

J. Hyper. Differential Equations

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We consider the wave equation, g ψ = 0, in fixed flat Friedmann-Lemaître-Robertson-Walker and Kasner spacetimes with topology R + × T 3 . We obtain generic blow up results for solutions to the wave equation towards the Big Bang singularity in both backgrounds. In particular, we characterize open sets of initial data prescribed at a spacelike hypersurface close to the singularity, which give rise to solutions that blow up in an open set of the Big Bang hypersurface {t = 0}. The initial data sets are characterized by the condition that the Neumann data should dominate, in an appropriate L 2 -sense, up to two spatial derivatives of the Dirichlet data. For these initial configurations, the L 2 (T 3 ) norms of the solutions blow up towards the Big Bang hypersurfaces of FLRW and Kasner with inverse polynomial and logarithmic rates respectively. Our method is based on deriving suitably weighted energy estimates in physical space. No symmetries of solutions are assumed.

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Section: Introduction and Main Theoremssupporting

confidence: 53%

The wave equation near flat Friedmann–Lemaître–Robertson–Walker and Kasner Big Bang singularities

Alho

Fournodavlos

Franzen

2019

J. Hyper. Differential Equations

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“…Interestingly, however, not all (nonconstant) solutions blow up, and in fact one of the difficulties in [2] is to formulate a genericity condition that excludes these special bounded solutions. This scenario, already found in [11], also occurs for solutions of the wave equation in the black hole region of the Schwarzschild spacetime (which can be thought of as a cosmological model approaching a Big Crunch), as discussed in [6]. The results in [10] suggest that a similar situation may occur near compact Cauchy horizons.…”

Section: Introduction and Statement Of The Main Resultssupporting

confidence: 57%

“…However, we do indeed suspect that this is the case for sufficiently regular solutions. Proving this would probably require the derivation of an accurate enough asymptotic expansion of all linear waves towards the singularity, as was done in [6].…”

Section: Introduction and Statement Of The Main Resultsmentioning

confidence: 99%

Solutions of the wave equation bounded at the Big Bang

Girão¹,

Natário²,

Silva³

2019

Class. Quantum Grav.

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By solving a singular initial value problem, we prove the existence of solutions of the wave equation g φ = 0 which are bounded at the Big Bang in the Friedmann-Lemaître-Robertson-Walker cosmological models. More precisely, we show that given any function A ∈ H 3 (Σ) (where Σ = R n , S n or H n models the spatial hypersurfaces) there exists a unique solution φ of the wave equation converging to A in H 1 (Σ) at the Big Bang, and whose time derivative is suitably controlled in L 2 (Σ).

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“…Finally, it is instructive to draw a comparison between the interior of Reissner-Nordström and the interior of Schwarzschild (Q = 0). As opposed to Reissner-Nordström discussed above, the Schwarzschild interior terminates at a singular boundary at which solutions to (1.1) generically blow-up (see [16]). In contrast, the non-singular and, moreover, Killing, Cauchy horizons (see Fig.…”

Section: Introductionmentioning

confidence: 90%

“…In view of the above, there has been a lot of recent activity analyzing the Cauchy problem on black hole interiors, e.g. [18,17,47,32,16]. However, for certain physical processes it is more natural to consider the scattering problem (see [19] for scattering on the exterior of black holes).…”

Section: Introductionmentioning

confidence: 99%

A Scattering Theory for Linear Waves on the Interior of Reissner–Nordström Black Holes

Kehle

Shlapentokh-Rothman

2019

Ann. Henri Poincaré

118

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We develop a scattering theory for the linear wave equation g ψ = 0 on the interior of Reissner-Nordström black holes, connecting the fixed frequency picture to the physical space picture. Our main result gives the existence, uniqueness and asymptotic completeness of finite energy scattering states. The past and future scattering states are represented as suitable traces of the solution ψ on the bifurcate event and Cauchy horizons. The heart of the proof is to show that after separation of variables one has uniform boundedness of the reflection and transmission coefficients of the resulting radial o.d.e. over all frequencies ω and . This is non-trivial because the natural T conservation law is sign-indefinite in the black hole interior. In the physical space picture, our results imply that the Cauchy evolution from the event horizon to the Cauchy horizon is a Hilbert space isomorphism, where the past (resp. future) Hilbert space is defined by the finiteness of the degenerate T energy fluxes on both components of the event (resp. Cauchy) horizon. Finally, we prove that, in contrast to the above, for a generic set of cosmological constants Λ, there is no analogous finite T energy scattering theory for either the linear wave equation or the Klein-Gordon equation with conformal mass on the (anti-) de Sitter-Reissner-Nordström interior. 6 Proof of Theorem 6: Breakdown of T energy scattering for cosmological constants Λ = 0 41 7 Proof of Theorem 7: Breakdown of T energy scattering for the Klein-Gordon equation 46 A Additional lemmata 47 References 51 on the interior of a Reissner-Nordström black hole, from the bifurcate event horizon H = H A ∪ H B ∪ B − to the bifurcate Cauchy horizon CH = CH A ∪CH B ∪B + , as depicted in Fig. 1. The first main result of our paper

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Generic Blow-Up Results for the Wave Equation in the Interior of a Schwarzschild Black Hole

Cited by 30 publications

References 38 publications

The wave equation near flat Friedmann–Lemaître–Robertson–Walker and Kasner Big Bang singularities

The wave equation near flat Friedmann–Lemaître–Robertson–Walker and Kasner Big Bang singularities

Solutions of the wave equation bounded at the Big Bang

A Scattering Theory for Linear Waves on the Interior of Reissner–Nordström Black Holes

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