1204.4786 (Maurice Kleman)
Maurice Kleman
The topological theory and the Volterra process are key tools for the classification of defects in Condensed Mater Physics. We employ the same methods to classify the 2D defects of a 4D maximally symmetric spacetime. These \textit{cosmic forms}, which are continuous, fall into three classes: i)- $m$-forms, akin to 3D space disclinations, analogous to Kibble's cosmic strings; ii)- $t$-forms, related to hyperbolic rotations; iii)- $r$-forms, never considered so far, related to null rotations. A detailed account of their metrics is presented. There are \textit{wedge} forms, whose singularities occupy a 2D world sheet, and \textit{twist} forms, whose singularities occupy a 3D world shell. $m$-forms are {compatible} with the cosmological principle of \textit{space} homogeneity and isotropy, $t$- and $r$-forms demand \textit{spacetime} homogeneity. $t$- and $r$-forms are typical of a vacuum obeying the perfect cosmological principle in a de Sitter spacetime. Cosmic forms may assemble into networks generating vanishing curvature.
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http://arxiv.org/abs/1204.4786
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