LEITE, C. S. R.; http://lattes.cnpq.br/0709318596898883; LEITE, Camilla dos Santos Rodrigues.
Resumo:
The study of the physical properties of galaxies is very important to understand the
behavior of the Universe. On the other hand, one of the great challenges of the General Theory of Relativity is to nd exact solutions which have a clear physical interpretation. Our work aims to obtain exact solutions of Einstein's equations that can represent models of galactic disks, by following an indirect method to avoid the di cult task of solving Einstein's equations directly. To this end, we consider the idea of a hypersurface embedded in a space of higher dimension, and we use the embedding formalism associated with the method of "displace", cut and reflect" (which can be considered as an adaptation of the known method of images, studied in electrostatics) on known vacuum solutions in order to generate solutions with disklike sources. This procedure, called the Embedding Method, is an e cient tool for modeling disks, as it allows great freedom in the choice of cutting hipersurfaces, and the consequent determination of physical properties (density, pressure, etc.) of the matter in the disk which is generated. Therefore, this method becomes more general than the conventional formulation of the method of "displace, cut and reflect", which works only to "plane" hypersurfaces (as viewed in the employed coordinate system). By applying the embedding formalism, we found that the material content of galactic disks, idealized as a in nitely thin disk of matter, is described by an energy-momentum tensor whose components can be written explicitly in terms of the embeeding functions. By studying individual cases, we reproduce some disk models found in the literature.