Tidal Deformation Bounds and Perturbation Transfer in Bounded Curvature Spacetimes

Abstract

We derive two model-independent results for spacetimes with globally bounded tidal fields. These are operational resolution scales of the local-inertial approximation and tidal dynamics; no spacetime discreteness is implied. Given an invariant bound λλ bound on the electric Riemann eigenvalues Eij R0i0j along freely falling worldlines, we prove (i)~a rigorous upper bound on accumulated geodesic deviation through any bounded curvature interior, controlled by τ*λ-1/2, and (ii)~the existence of a critical wavenumber k*τ*-1 separating adiabatic from non-adiabatic perturbation transfer through high-curvature epochs, with Bogoliubov coefficients exponentially suppressed for k\,τ* 1. Both results depend only on the tidal bound (and, for mode transfer, on a mild timescale assumption for the curvature-driven effective potential) and are otherwise insensitive to metric details. For preparation, we collect the standard operational consequences of bounded curvature, including the accuracy-dependent local-inertial domain L LI()\, λ-1/2 and, for conformally flat cores in four dimensions, the benchmark ratio τ*/L*=241/4 with L* K-1/4. We quantify the robustness of this coefficient under departures from maximal symmetry via the Weyl-to-Kretschmann ratio εC. The general framework is validated numerically in the extremal Hayward geometry.