Birkhoff rigidity from a covariant optical seed
Abstract
We present a local seed-to--Kerr--Schild route to Birkhoff rigidity in four-dimensional spherical vacuum gravity. On the two-dimensional orbit space, the areal radius determines a scalar , and the reduced vacuum equations imply . We show that the normalized one-forms and are closed, so that the null combinations are exact null seed forms. Integrating these yields local Eddington--Finkelstein coordinates in which the metric takes Kerr--Schild form over a flat background. We then prove the corresponding uniqueness statement in the stationary optical sector: spherical symmetry forces the inverse optical seed to equal , equivalently the optical seed to equal , and the resulting seed data reconstruct the Schwarzschild family. Thus, Birkhoff rigidity is paired with a spherical converse theorem in the stationary optical framework: Schwarzschild is the unique spherically symmetric stationary vacuum Kerr--Schild geometry generated by a nowhere-vanishing optical seed.
Cite
@article{arxiv.2604.09830,
title = {Birkhoff rigidity from a covariant optical seed},
author = {D. A. Easson},
journal= {arXiv preprint arXiv:2604.09830},
year = {2026}
}
Comments
6 pages