Integration of the Lane–Emden equation for relativistic anisotropic polytropes through gravitational decoupling: a novel approach

D. Santana; E. Fuenmayor; E. Contreras

doi:10.1140/epjc/s10052-022-10683-5

Integration of the Lane–Emden equation for relativistic anisotropic polytropes through gravitational decoupling: a novel approach

D. Santana
, E. Fuenmayor
, E. Contreras^*

^*Corresponding author for this work

Física

Universidad San Francisco de Quito
Universidad Central de Venezuela, Facultad de Ciencias

Research output: Contribution to journal › Article › peer-review

26 Scopus citations

Abstract

In this work we propose a novel approach to integrate the Lane–Emden equations for relativistic anisotropic polytropes. We take advantage of the fact that Gravitational Decoupling allows to decrease the number of degrees of freedom once a well known solution of the Einstein field equations is provided as a seed so after demanding the polytropic equation for the radial pressure the system is automatically closed. The approach not only allows to extend both isotropic or anisotropic known solutions but simplifies the computation of the Tolman mass whenever the Minimal Geometric Deformation is considered given that the g_tt component of the metric remains unchanged. We illustrate how the the method works by analyzing the solutions obtained from Tolman IV, Durgapal IV and Wymann IIa isotropic systems as a seed for the integration.

Original language	English
Article number	703
Journal	European Physical Journal C
Volume	82
Issue number	8
DOIs	https://doi.org/10.1140/epjc/s10052-022-10683-5
State	Published - Aug 2022

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title = "Integration of the Lane–Emden equation for relativistic anisotropic polytropes through gravitational decoupling: a novel approach",

abstract = "In this work we propose a novel approach to integrate the Lane–Emden equations for relativistic anisotropic polytropes. We take advantage of the fact that Gravitational Decoupling allows to decrease the number of degrees of freedom once a well known solution of the Einstein field equations is provided as a seed so after demanding the polytropic equation for the radial pressure the system is automatically closed. The approach not only allows to extend both isotropic or anisotropic known solutions but simplifies the computation of the Tolman mass whenever the Minimal Geometric Deformation is considered given that the gtt component of the metric remains unchanged. We illustrate how the the method works by analyzing the solutions obtained from Tolman IV, Durgapal IV and Wymann IIa isotropic systems as a seed for the integration.",

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AU - Contreras, E.

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AB - In this work we propose a novel approach to integrate the Lane–Emden equations for relativistic anisotropic polytropes. We take advantage of the fact that Gravitational Decoupling allows to decrease the number of degrees of freedom once a well known solution of the Einstein field equations is provided as a seed so after demanding the polytropic equation for the radial pressure the system is automatically closed. The approach not only allows to extend both isotropic or anisotropic known solutions but simplifies the computation of the Tolman mass whenever the Minimal Geometric Deformation is considered given that the gtt component of the metric remains unchanged. We illustrate how the the method works by analyzing the solutions obtained from Tolman IV, Durgapal IV and Wymann IIa isotropic systems as a seed for the integration.

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JO - European Physical Journal C

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Integration of the Lane–Emden equation for relativistic anisotropic polytropes through gravitational decoupling: a novel approach

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