An approximate global solution of Einstein’s equations for a rotating finite body

Cabezas, José A.; Martín, Jesús Izquierdo; Molina, Alfred; Ruiz, E.

doi:10.1007/s10714-007-0414-6

Cited by 31 publications

(77 citation statements)

References 24 publications

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“…As we will see shortly, the deviation from algebraically special cases can arise first when considering the second order terms in the rotational parameter. Here we require the interior solution to remain Petrov type D for slow rotation, thereby completing the system of field equations (3), (6), (7), (8), (9), (10) and (19) by a further condition, which in some sense plays the role of an equation of state.…”

Section: A the Field Equationsmentioning

confidence: 99%

“…For a review of relativistic rotating stars see [5]. In [6] global models for slowly rotating bodies in the post-Minkowskian approximation are treated. In a recent paper [7] second order perturbation theory for the matching of general stationary axisymmetric bodies to an asymptotically flat vacuum has been put on a more solid mathematical ground and the exterior metric is determined to second order.…”

Section: Introductionmentioning

confidence: 99%

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Slowly rotating fluid balls of Petrov type D

et al. 2007

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The second order perturbative field equations for slowly and rigidly rotating perfect fluid balls of Petrov type D are solved numerically. It is found that all the slowly and rigidly rotating perfect fluid balls up to second order, irrespective of Petrov type, may be matched to a possibly non-asymptotically flat stationary axisymmetric vacuum exterior. The Petrov type D interior solutions are characterized by five integration constants, corresponding to density and pressure of the zeroth order configuration, the magnitude of the vorticity, one more second order constant and an independent spherically symmetric second order small perturbation of the central pressure. A four-dimensional subspace of this five-dimensional parameter space is identified for which the solutions can be matched to an asymptotically flat exterior vacuum region. Hence these solutions are completely determined by the spherical configuration and the magnitude of the vorticity. The physical properties like equations of state, shapes and speeds of sound are determined for a number of solutions.

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Section: A the Field Equationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Slowly rotating fluid balls of Petrov type D

et al. 2007

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“…As in our previous work [12,13,14,15] on the rigid rotation problem, here we introduce a post-Minkowskian parameter, λ, and a dimensionless rotation parameter, Ω = λ −1/2 ωr 0 , where r 0 is the radius of the source in the nonrotation limit. Then we can rewrite (12) as:…”

Section: Approximation Schemementioning

confidence: 99%

“…In some previous papers [11,12,13,14], we studied this problem for rigid rotation; and now, we will use the same approximation scheme to study a differentially rotating perfect fluid.…”

Section: Introductionmentioning

confidence: 99%

An approximate global solution of Einstein’s equations for a differentially rotating compact body

Molina

Ruiz

2017

Gen Relativ Gravit

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We obtain an approximate global stationary and axisymmetric solution of Einstein's equations which can be thought of as a simple star model: a self-gravitating perfect fluid ball with a differential rotation motion pattern. Using the post-Minkowskian formalism (weak-field approximation) and considering rotation as a perturbation (slow-rotation approximation), we find approximate interior and exterior (asymptotically flat) solutions to this problem in harmonic coordinates. Interior and exterior solutions are matched, in the sense described by Lichnerowicz, on the surface of zero pressure, to obtain a global solution. The resulting metric depends on four arbitrary constants: mass density; rotational velocity at r = 0; a parameter that accounts for the change in rotational velocity through the star; and the star radius in the non-rotation limit. The mass, angular momentum, quadrupole moment and other constants of the exterior metric are determined in terms of these four parameters. PACS number(s) 04.40.Nr, 04.20.Jb

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“…Yet another method used for the construction of models of slowly rotating stars has recently [20,21] produced a particular model to second order in the approximation for a rigidly rotating and constant density perfect-fluid interior. The method is based on a two-parameter perturbation scheme, combining the post-Minkowskian and slow-rotation approximations, both taken up to the first non-linear level.…”

Section: Introductionmentioning

confidence: 99%

Stationary axisymmetric exteriors for perturbations of isolated bodies in general relativity, to second order

2007

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Perturbed stationary axisymmetric isolated bodies, e.g. stars, represented by a matter-filled interior and an asymptotically flat vacuum exterior joined at a surface where the Darmois matching conditions are satisfied, are considered. The initial state is assumed to be static. The perturbations of the matching conditions are derived and used as boundary conditions for the perturbed Ernst equations in the exterior region. The perturbations are calculated to second order. The boundary conditions are overdetermined: necessary and sufficient conditions for their compatibility are derived. The special case of perturbations of spherical bodies is given in detail.

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An approximate global solution of Einstein’s equations for a rotating finite body

Cited by 31 publications

References 24 publications

Slowly rotating fluid balls of Petrov type D

Slowly rotating fluid balls of Petrov type D

An approximate global solution of Einstein’s equations for a differentially rotating compact body

Stationary axisymmetric exteriors for perturbations of isolated bodies in general relativity, to second order

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