Spherically symmetric isothermal fluids in f(R, T) gravity

We analyze the isothermal property in static fluid spheres within the framework of the modified f ( R ,  T ) theory of gravitation. The equation of pressure isotropy of the standard Einstein theory is preserved however, the energy density and pressure are expressed in terms of both gravitational pot...

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Bibliographic Details
Published inThe European physical journal. C, Particles and fields Vol. 78; no. 9; pp. 1 - 8
Main Author Hansraj, Sudan
Format Journal Article
LanguageEnglish
Published Berlin/Heidelberg Springer Berlin Heidelberg 01.09.2018
Springer
Springer Nature B.V
SpringerOpen
Subjects
Analysis
Astronomy
Astrophysics and Cosmology
Computational fluid dynamics
Density
Elementary Particles
Equations of state
Flux density
Gravitation
Gravity (Force)
Hadrons
Heavy Ions
Hyperspaces
Isotropy
Measurement Science and Instrumentation
Nuclear Energy
Nuclear Physics
Physics
Physics and Astronomy
Quantum Field Theories
Quantum Field Theory
Regular Article - Theoretical Physics
Relativity
Stress concentration
String Theory
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Summary:We analyze the isothermal property in static fluid spheres within the framework of the modified f ( R ,  T ) theory of gravitation. The equation of pressure isotropy of the standard Einstein theory is preserved however, the energy density and pressure are expressed in terms of both gravitational potentials. Invoking the isothermal prescription requires that the isotropy condition assumes the role of a consistency condition and an exact model generalizing that of general relativity is found. Moreover it is found that the Einstein model is unstable and acausal while the f ( R ,  T ) counterpart is well behaved on account of the freedom available through an additional coupling constant. The case of a constant spatial gravitational potential is considered and the complete model is determined. This model is markedly different from its Einstein counterpart which is known to be isothermal. Dropping the restriction on the density and imposing a linear barotropic equation of state generates an exact solution and consequently a stellar distribution as the vanishing of the pressure is possible and a boundary hypersurface exists. Finally we comment on the case of relaxing the equation of state but demanding an inverse square fall-off of the density – this case proves intractable.
ISSN:1434-6044
1434-6052
DOI:10.1140/epjc/s10052-018-6194-1