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dc.contributor.advisorMaharaj., S. D.
dc.contributor.advisorGovinder, Kesh S.
dc.creatorNyonyi, Yusuf.
dc.date.accessioned2015-01-07T12:34:52Z
dc.date.available2015-01-07T12:34:52Z
dc.date.created2013
dc.date.issued2015-01-07
dc.identifier.urihttp://hdl.handle.net/10413/11834
dc.descriptionPh. D. University of KwaZulu-Natal, Durban 2013.en
dc.description.abstractWe study shear-free heat conducting spherically symmetric gravitating fluids defined in four and higher dimensional spacetimes. We analyse models that are both uncharged and charged via the pressure isotropy condition emanating from the Einstein field equations and the Einstein-Maxwell system respectively. Firstly, we consider the uncharged model defined in higher dimensions, and we use the algorithm due to Deng to generate new exact solutions. Three new metrics are identified which contain the results of four dimensions as special cases. We show graphically that the matter variables are well behaved and the speed of sound is causal. Secondly, we use Lie's group theoretic approach to study the condition of pressure isotropy of a charged relativistic model in four dimensions. The Lie symmetry generators that leave the equation invariant are found. We provide exact solutions to the gravitational potentials using the symmetries admitted by the equation. The new exact solutions contain earlier results without charge. We show that new charged solutions related to the Lie symmetries, that are generalizations of conformally at metrics, may be generated using the algorithm of Deng. Finally, we extend our study to find models of charged gravitating fluids defined in higher dimensional manifolds. The Lie symmetry generators related to the generalized pressure isotropy condition are found, and exact solutions to the gravitational potentials are generated. The new exact solutions contain earlier results obtained in four dimensions. Using particular Lie generators, we are able to provide forms for the gravitational potentials or reduce the order of the master equation to a first order nonlinear differential equation. Exact expressions for the temperature pro les, from the transport equation for both the causal and noncausal cases, in higher dimensions are obtained, generalizing previous results. In summary, the Deng algorithm and Lie analysis prove to be useful approaches in generating new models for gravitating fluids.en
dc.language.isoen_ZAen
dc.subjectGravitation.en
dc.subjectEinstein field equations.en
dc.subjectLie groups.en
dc.subjectDifferential equations.en
dc.subjectAstrophysics.en
dc.subjectTheses--Applied mathematics.en
dc.titleGroup theoretic approach to heat conducting gravitating systems.en
dc.typeThesisen


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