Abstract

We revisit the neutral (uncharged) solutions that describe Einstein’s clusters with matters in the frame of Weitzenböck geometry. To this end, we use a tetrad field with non-diagonal spherical symmetry which gives vanishing of the off-diagonal components of the gravitational field equations. The cluster solutions are calculated by using an anisotropic energy–momentum tensor. We solve the field equations using two novel assumptions. First, we use an equation of state that relates density with tangential pressure, and then we assume a specific form of one of the metric potentials in addition to the assumption of the vanishing of radial pressure to make the system of differential equations in a closed-form. The resulting solutions are coincide with the literature however , ,in, ,this, ,study, ,we, ,constrain,, the,, constants , ,of, , integration, , from, , ,the, , matching,, of, ,boundary condition, , in a,, way ,,different,, from,, that,, presented ,,in ,,the,, literature. Among many things presented in this study, we investigate the static stability specification and show that our model is consistent with a real compact start except that the tangential pressure has a vanishing value at the center of the star which is not accepted from the physical viewpoint of a real compact star. We conclude that the model that has vanishing radial pressure in the frame of Einstein’s theory is not a physical model. Therefore, we extend this study and derive a new compact star without assuming the vanishing of the redial pressure but instead we assume new form of the metric potentials. We repeat our procedure done in the case of vanishing radial pressure and show in details that the new compact star is more realistic from different physical viewpoints of real compact stellar.

Highlights

  • To investigate the importance of astrophysics or astronomy with gravitational waves, the theory of general relativity (GR) plays an essential role in astrophysical systems like compact objects and radiation with high energy usually from strong gravity field around neutron stars and black holes [1].Recently, observations show that our universe is experiencing cosmic acceleration

  • We have explored and discussed the model of compact stars which mimic clusters of Weitzenböck geometry

  • The non-vacuum gravitational field equations have been applied to a tetrad field having non-diagonal components and has two unknown functions, μ and ν

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Summary

Introduction

To investigate the importance of astrophysics or astronomy with gravitational waves, the theory of general relativity (GR) plays an essential role in astrophysical systems like compact objects and radiation with high energy usually from strong gravity field around neutron stars and black holes [1]. The compact objects filled with fluids with their anisotropy have been attracted many researchers and their structure and evolutional processes have been studied [51,52,53,54,55,56,57,58,59,60,61,62,63,64] It is the aim of this study to apply a non-diagonal tetrad field that possesses spherical symmetry to the nonvacuum equation of motions of Weitzenböck geometry theory using some physically-motivated assumptions and try to derive novel models in this theory that are different from the unphysical models presented in the literature.

Basic formulae of Weitzenböck geometry
Neutral compact stars
Matching of boundary
Energy conditions for compact stars
Tolman–Oppenheimer–Volkoff equation and the analyses of the equilibrium
Stability in the static state
Real compact star
Discussions and conclusions

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