Prove nonlinear instability of Kerr-AdS in a theorem (beyond numerics/backreaction studies).

Summary

Prove nonlinear instability of Kerr-AdS in a theorem (beyond numerics/backreaction studies).

Why this matters

Moves simulations/mode constructions into PDE-level theorem.

Exact scope

Background / setting

anti de sitter general relativity context; see family and coupling tags for matter model.

Equation type

PDE level: full-einstein.

Linearity

both linearized and fully nonlinear aspects

Regularity

Smooth / Sobolev hypotheses must be stated precisely in any final theorem; this provisional entry does not fix minimal regularity.

Parameter regime

Subextremal Kerr (or Kerr–de Sitter where tagged); spectral parameters $(l,m)$ and frequency $ω$ regimes as in cited microlocal frameworks.

Asymptotics

anti de sitter

Gauge / formulation

State gauge/fixing class compatible with cited stability or interior programs (e.g. generalized harmonic, double-null interior charts).

Status explanation

Partial results exist in adjacent regimes (see references); sharp alignment with this page’s exact target remains open.

Problem statement

Prove nonlinear instability of Kerr-AdS in a theorem (beyond numerics/backreaction studies).

What is already known

• Named papers in the reference list establish partial or neighboring results under explicit hypotheses; treat those as the proved baseline.
  Regime: As stated in cited references (often restricted parameters or linearized settings).
  Orients readers to literature without equating it with the full title-length target.

Progress summary: Manifest rationale: Moves simulations/mode constructions into PDE-level theorem.

What remains open

Prove nonlinear instability of Kerr-AdS in a theorem (beyond numerics/backreaction studies).

Mathematical prerequisites

Match hypotheses to primary sources cited on this page; state minimal regularity, gauge class, and parameter windows in any claimed theorem.

Completion criteria

Prove a theorem or give a rigorous counterexample that matches the scoped statement under explicitly listed hypotheses.

Implications if solved

Impact depends on the solved formulation; sharpen once the statement is pinned to a literature-compatible theorem.

Formal verification suitability

FV: low

Global PDE or phenomenological target; lemma-level formalization may be possible after scoping.

See Formal verification for how this database uses these labels.

References

• primary Global analysis of linear waves on Kerr–de Sitter space — Hintz, Vasy (2016)
  Linear wave decay and spectral gap on Kerr–de Sitter; standard microlocal input for $Lambda>0$ decay.
• survey Brief introduction to the nonlinear stability of Kerr — Klainerman, Szeftel (2022)
  Program overview, gauge structure, and relation between linear tools and nonlinear stability.

Related problems

Related by shared tags

Heuristic matches on family, cluster, equation level, asymptotics, and relevance.

• K-637 — Prove rigorous existence and nonlinear stability/instability classification of Kerr-AdS endstates (black resonators/geons).
• K-010 — Nonlinear superradiant endstates in Kerr–AdS
• K-688 — Prove a fully rigorous PDE theorem for nonlinear superradiant instability of Kerr in a confining setting (mirror/AdS).
• K-603 — Prove nonlinear stability of Kerr with quantitative scattering (asymptotic completeness near Kerr).
• K-660 — Establish a full nonlinear ringdown plus tail decomposition for near-Kerr vacuum spacetimes.
• K-662 — Develop a rigorous theory of excitation factors in Kerr and prove universal bounds across (l,m).
• K-683 — Prove a sharp characterization of the Kerr trapped set as a normally hyperbolic invariant manifold uniformly in a/M.

Editorial / maintainer notes

Source manifest: N-038 (expansion_from_manifest.tsv). Numeric footnotes from the original table are not reproduced in this repository.