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Charged Shear-Free Fluids and Complexity in First Integrals

Authors:	Sfundo C. Gumede Keshlan S. Govinder Sunil D. Maharaj

Affiliation:	1.Astrophysics Research Centre, School of Mathematics, Statistics and Computer Science, University of KwaZulu-Natal, Private Bag X54001, Durban 4000, South Africa; (S.C.G.); (K.S.G.);2.Department of Mathematical Sciences, Mangosuthu University of Technology, P.O. Box 12363, Jacobs 4026, South Africa

Abstract:	The equation $y_{x x} = f (x) y^{2} + g (x) y^{3}$ is the charged generalization of the Emden-Fowler equation that is crucial in the study of spherically symmetric shear-free spacetimes. This version arises from the Einstein–Maxwell system for a charged shear-free matter distribution. We integrate this equation and find a new first integral. For this solution to exist, two integral equations arise as integrability conditions. The integrability conditions can be transformed to nonlinear differential equations, which give explicit forms for $f (x)$ and $g (x)$ in terms of elementary and special functions. The explicit forms $f (x) \sim \frac{1}{x^{5}} {(1 - \frac{1}{x})}^{- 11 / 5}$ and $g (x) \sim \frac{1}{x^{6}} {(1 - \frac{1}{x})}^{- 12 / 5}$ arise as repeated roots of a fourth order polynomial. This is a new solution to the Einstein-Maxwell equations. Our result complements earlier work in neutral and charged matter showing that the complexity of a charged self-gravitating fluid is connected to the existence of a first integral.

Keywords:	relativistic fluids Einstein-Maxwell field equations first integrals

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