We obtain an approximate global stationary and axisymmetric solution of Einstein's equations which can be considered as a simple star model: a self-gravitating perfect fluid ball with constant mass density rotating in rigid motion. 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 and quo-harmonic coordinates. In both cases, interior and exterior solutions are matched, in the sense of Lichnerowicz, on the surface of zero pressure to obtain a global solution. The resulting metric depends on three arbitrary constants: mass density, rotational velocity and ...
A method for interpreting discontinuities of the twist potential of vacuum stationary axisymmetric s...
International audienceWe study spherically symmetric solutions to the Einstein–Euler equations which...
A pseudo-field theoretic reformulation of the Newton--Euler dynamics of isolated, gravitating fluids...
Using the Post-Minkowskian formalism and considering rotation as a perturbation, we compute an appro...
In the framework of general relativity, a description of the matching conditions between two rotatin...
The linearized Einstein equations for a static, spherically symmetric fluid ball and its empty surro...
We present a method for constructing stationary, asymptotically flat, rotating solutions of Einstein...
Perturbed stationary axisymmetric isolated bodies, e.g. stars, represented by a matter-filled interi...
We study how the changes of coordinates between the class of harmonic coordinates affect the anality...
Rotating bodies of finite size in the context of general relativity remain very poorly understood; o...
The various schemes for studying rigidly rotating perfect fluids in general relativity are reviewed....
A global solution of the Einstein equations is given, consisting of a perfect fluid interior and a v...
In this thesis, we study slowly rotating relativistic stars by modeling them as perfect fluids. The ...
The second order perturbative field equations for slowly and rigidly rotating perfect fluid balls of...
Cataldo has found all rigidly rotating self-gravitating perfect fluid solutions in 2+1 dimensions wi...
A method for interpreting discontinuities of the twist potential of vacuum stationary axisymmetric s...
International audienceWe study spherically symmetric solutions to the Einstein–Euler equations which...
A pseudo-field theoretic reformulation of the Newton--Euler dynamics of isolated, gravitating fluids...
Using the Post-Minkowskian formalism and considering rotation as a perturbation, we compute an appro...
In the framework of general relativity, a description of the matching conditions between two rotatin...
The linearized Einstein equations for a static, spherically symmetric fluid ball and its empty surro...
We present a method for constructing stationary, asymptotically flat, rotating solutions of Einstein...
Perturbed stationary axisymmetric isolated bodies, e.g. stars, represented by a matter-filled interi...
We study how the changes of coordinates between the class of harmonic coordinates affect the anality...
Rotating bodies of finite size in the context of general relativity remain very poorly understood; o...
The various schemes for studying rigidly rotating perfect fluids in general relativity are reviewed....
A global solution of the Einstein equations is given, consisting of a perfect fluid interior and a v...
In this thesis, we study slowly rotating relativistic stars by modeling them as perfect fluids. The ...
The second order perturbative field equations for slowly and rigidly rotating perfect fluid balls of...
Cataldo has found all rigidly rotating self-gravitating perfect fluid solutions in 2+1 dimensions wi...
A method for interpreting discontinuities of the twist potential of vacuum stationary axisymmetric s...
International audienceWe study spherically symmetric solutions to the Einstein–Euler equations which...
A pseudo-field theoretic reformulation of the Newton--Euler dynamics of isolated, gravitating fluids...