English

Modelling anisotropic fluid spheres in general relativity

General Relativity and Quantum Cosmology 2017-11-29 v3

Abstract

We argue that an arbitrary general relativistic static anisotropic fluid sphere, (static and spherically symmetric but with transverse pressure not equal to radial pressure), can nevertheless be successfully mimicked by suitable linear combinations of theoretically attractive and quite simple classical matter: a classical (charged) isotropic perfect fluid, a classical electromagnetic field, and a classical (minimally coupled) scalar field. While the most general decomposition is not unique, a preferred minimal decomposition can be constructed that is unique. We show how the classical energy conditions for the anisotropic fluid sphere can be related to energy conditions for the isotropic perfect fluid, electromagnetic field, and scalar field components of the model. Furthermore we show how this decomposition relates to the distribution of both electric charge density and scalar charge density throughout the model. The generalized TOV equation implies that the perfect fluid component in this model is automatically in internal equilibrium, with pressure forces, electric forces, and scalar forces balancing the gravitational pseudo-force. Consequently, we can build theoretically attractive matter models that can be used to mimic almost any static spherically symmetric spacetime.

Keywords

Cite

@article{arxiv.1501.07044,
  title  = {Modelling anisotropic fluid spheres in general relativity},
  author = {Petarpa Boonserm and Tritos Ngampitipan and Matt Visser},
  journal= {arXiv preprint arXiv:1501.07044},
  year   = {2017}
}

Comments

V1: 6 pages; V2: now 7 pages; 7 references added; no physics changes; V3: Revised and reformatted; now 15 pages in World Scientific style. Some extra discussion added. 5 more references added. This version accepted for publication in IJMPD

R2 v1 2026-06-22T08:14:43.742Z