Spherically Symmetric Exact Vacuum Solutions in Einstein-Aether Theory

We study spherically symmetric spacetimes in Einstein-aether theory in three different coordinate systems, the isotropic, Painlevè-Gullstrand, and Schwarzschild coordinates, in which the aether is always comoving, and present both time-dependent and time-independent exact vacuum solutions. In particular, in the isotropic coordinates we find a class of exact static solutions characterized by a single parameter c14 in closed forms, which satisfies all the current observational constraints of the theory, and reduces to the Schwarzschild vacuum black hole solution in the decoupling limit (c14=0). However, as long as c14≠0, a marginally trapped throat with a finite non-zero radius always exists, and on one side of it the spacetime is asymptotically flat, while on the other side the spacetime becomes singular within a finite proper distance from the throat, although the geometric area is infinitely large at the singularity. Moreover, the singularity is a strong and spacetime curvature singularity, at which both of the Ricci and Kretschmann scalars become infinitely large.

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A Relativistic Algorithm with Isotropic Coordinates

Advances in Mathematical Physics ◽

10.1155/2013/905168 ◽

2013 ◽

Vol 2013 ◽

pp. 1-6 ◽

Cited By ~ 7

Author(s):

S. A. Ngubelanga ◽

S. D. Maharaj

Keyword(s):

Spherically Symmetric ◽

Conformally Flat ◽

Einstein Field Equations ◽

Elementary Functions ◽

Field Equations ◽

Isotropic Coordinates ◽

New Exact Solutions ◽

Symmetric Spacetimes ◽

Particular Solution ◽

Conformally Flat Metric

We study spherically symmetric spacetimes for matter distributions with isotropic pressures. We generate new exact solutions to the Einstein field equations which also contain isotropic pressures. We develop an algorithm that produces a new solution if a particular solution is known. The algorithm leads to a nonlinear Bernoulli equation which can be integrated in terms of arbitrary functions. We use a conformally flat metric to show that the integrals may be expressed in terms of elementary functions. It is important to note that we utilise isotropic coordinates unlike other treatments.

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Spherically symmetric vacuum solutions arising from trace dynamics modifications to gravitation

International Journal of Modern Physics D ◽

10.1142/s021827181550011x ◽

2015 ◽

Vol 24 (02) ◽

pp. 1550011 ◽

Cited By ~ 3

Author(s):

Stephen L. Adler ◽

Fethi M. Ramazanoğlu

Keyword(s):

Einstein Equations ◽

Polar Coordinates ◽

Spherically Symmetric ◽

Static Case ◽

Isotropic Coordinates ◽

Physical Singularity ◽

Symmetric Vacuum ◽

Polar Radius ◽

Vacuum Solutions ◽

Time Dependent Solution

We derive the equations governing static, spherically symmetric vacuum solutions to the Einstein equations, as modified by the frame-dependent effective action (derived from trace dynamics) that gives an alternative explanation of the origin of "dark energy". We give analytic and numerical results for the solutions of these equations, first in polar coordinates, and then in isotropic coordinates. General features of the static case are that: (i) there is no horizon, since g00 is nonvanishing for finite values of the polar radius, and only vanishes (in isotropic coordinates) at the internal singularity, (ii) the Ricci scalar R vanishes identically, and (iii) there is a physical singularity at cosmological distances. The large distance singularity may be an artifact of the static restriction, since we find that the behavior at large distances is altered in a time-dependent solution using the McVittie Ansatz.

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