Excising Curvature Singularities from General Relativity

Abstract

This thesis operates within the framework of general relativity without curvature singularities. The motivation for this framework is explored, and several conclusions are drawn with a look towards future research. There are many ways to excise curvature singularities from general relativity; a full list of desirable constraints on candidate geometries is presented. Several specific candidate spacetimes in both spherical symmetry and axisymmetry are rigorously analysed, typically modelling (charged or uncharged) regular black holes or traversable wormholes. Broadly, these are members of the family of black-bounce spacetimes, and the family of black holes with asymptotically Minkowski cores. Related thin-shell traversable wormhole constructions are also explored, as well as a brief look at the viability of thin-shell Dyson mega-spheres. The eye of the storm geometry is analysed, and discovered to be very close to an idealised candidate geometry within this framework. It is found to contain highly desirable features, and is not precluded by currently available measurements. For all spacetimes discussed, particular focus is placed on the extraction of (potential) astrophysical observables in principle falsifiable/verifiable by the observational and experimental communities. A cogent effort is made to streamline the discourse between theory and experiment, and to begin filling the epistemological gap, which will enable the various communities involved to optimise the advancement of physics via the newly available observational technologies (such as LIGO/Virgo, and the upcoming LISA). Furthermore, three somewhat general theorems are presented, and two new geometries are introduced for the first time to the literature.