Self-gravitating field configurations: The role of the energy-momentum trace
arXiv:1412.3808 · doi:10.1016/j.physletb.2014.11.019
Abstract
Static spherically-symmetric matter distributions whose energy-momentum tensor is characterized by a non-negative trace are studied analytically within the framework of general relativity. We prove that such field configurations are necessarily highly relativistic objects. In particular, for matter fields with $T\geqα\cdotÏ\geq0$ (here $T$ and $Ï$ are respectively the trace of the energy-momentum tensor and the energy density of the fields, and $α$ is a non-negative constant), we obtain the lower bound $\text{max}_r\{2m(r)/r\}>(2+2α)/(3+2α)$ on the compactness (mass-to-radius ratio) of regular field configurations. In addition, we prove that these compact objects necessarily possess (at least) {\it two} photon-spheres, one of which exhibits {\it stable} trapping of null geodesics. The presence of stable photon-spheres in the corresponding curved spacetimes indicates that these compact objects may be nonlinearly unstable. We therefore conjecture that a negative trace of the energy-momentum tensor is a {\it necessary} condition for the existence of stable, soliton-like (regular) field configurations in general relativity.
11 pages