English

Projective Compactness and Conformal Boundaries

Differential Geometry 2016-11-08 v2

Abstract

Let M\overline{M} be a smooth manifold with boundary M\partial M and interior MM. Consider an affine connection \nabla on MM for which the boundary is at infinity. Then \nabla is projectively compact of order α\alpha if the projective structure defined by \nabla smoothly extends to all of M\overline{M} in a specific way that depends on no particular choice of boundary defining function. Via the Levi--Civita connection, this concept applies to pseudo--Riemannian metrics on MM. We study the relation between interior geometry and the possibilities for compactification, and then develop the tools that describe the induced geometry on the boundary. We prove that a pseudo--Riemannian metric on MM which is projectively compact of order two admits a certain asymptotic form. This form was known to be sufficient for projective compactness, so the result establishes that it provides an equivalent characterization. From a projectively compact connection on MM, one obtains a projective structure on M\overline{M}, which induces a conformal class of (possibly degenerate) bundle metrics on the tangent bundle to the hypersurface M\partial M. Using the asymptotic form, we prove that in the case of metrics, which are projectively compact of order two, this boundary structure is always non--degenerate. We also prove that in this case the metric is necessarily asymptotically Einstein, in a natural sense. Finally, a non--degenerate boundary geometry gives rise to a (conformal) standard tractor bundle endowed with a canonical linear connection, and we explicitly describe these in terms of the projective data of the interior geometry.

Keywords

Cite

@article{arxiv.1406.4225,
  title  = {Projective Compactness and Conformal Boundaries},
  author = {Andreas Cap and A. Rod Gover},
  journal= {arXiv preprint arXiv:1406.4225},
  year   = {2016}
}

Comments

Substantially revised, including simpler arguments for many of the main results. 32 pages, comments are welcome

R2 v1 2026-06-22T04:39:53.821Z