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Gravitational collapse of an anisotropic fluid and interacting vacuum energy density: the curvature effect. (English) Zbl 1457.85006

Summary: In this paper, we study the gravitational collapse of a spherical symmetric star constituted of matter interacting with vacuum energy density \(\Lambda\) in the background of spacetime curvature. We consider the gravitational collapse for closed, flat, and hyperbolic spacetime geometry \((k=1,0,-1)\). We take the process of gravitational collapse for an anisotropic fluid interacting with a growing vacuum energy density by taking a complete physically general-relativistic approach in the background of spacetime curvature. Here, we achieved analytic solutions with some assumptions of physical significance. We executed and interpreted the solutions for several cases of the equation of state parameters, \((l,\omega)\). In all physical cases, we investigate the formation of a black hole and the naked singularity.

MSC:

85A15 Galactic and stellar structure
83C55 Macroscopic interaction of the gravitational field with matter (hydrodynamics, etc.)
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