Spacetime topology is the topological structure of spacetime, a topic studied primarily in general relativity. This physical theory models gravitation as the curvature of a four dimensional Lorentzian manifold (a spacetime) and the concepts of topology thus become important in analysing local as well as global aspects of spacetime. The study of spacetime topology is especially important in physical cosmology. There are two main types of topology for a spacetime M. As with any manifold, a spacetime possesses a natural manifold topology. Here the open sets are the image of open sets in . Definition: The topology in which a subset is open if for every timelike curve there is a set in the manifold topology such that . It is the finest topology which induces the same topology as does on timelike curves. Strictly finer than the manifold topology. It is therefore Hausdorff, separable but not locally compact. A base for the topology is sets of the form for some point and some convex normal neighbourhood . ( denote the chronological past and future). The Alexandrov topology on spacetime, is the coarsest topology such that both and are open for all subsets . Here the base of open sets for the topology are sets of the form for some points . This topology coincides with the manifold topology if and only if the manifold is strongly causal but it is coarser in general. Note that in mathematics, an Alexandrov topology on a partial order is usually taken to be the coarsest topology in which only the upper sets are required to be open. This topology goes back to Pavel Alexandrov. Nowadays, the correct mathematical term for the Alexandrov topology on spacetime (which goes back to Alexandr D. Alexandrov) would be the interval topology, but when Kronheimer and Penrose introduced the term this difference in nomenclature was not as clear, and in physics the term Alexandrov topology remains in use. Events connected by light have zero separation. The plenum of spacetime in the plane is split into four quadrants, each of which has the topology of R2.

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Theoretical physics is a branch of physics that employs mathematical models and abstractions of physical objects and systems to rationalize, explain and predict natural phenomena. This is in contrast to experimental physics, which uses experimental tools to probe these phenomena. The advancement of science generally depends on the interplay between experimental studies and theory. In some cases, theoretical physics adheres to standards of mathematical rigour while giving little weight to experiments and observations.
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