240 research outputs found

    The Energy Distribution in a Static Spherically Symmetric Nonsingular Black Hole Space-Time

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    We calculate the energy distribution in a static spherically symmetric nonsingular black hole space-time by using the Tolman's energy-momentum complex. All the calculations are performed in quasi-Cartesian coordinates. The energy distribution is positive everywhere and be equal to zero at origin. We get the same result as obtained by Y-Ching Yang by using the Einstein's and Weinberg's prescriptions.Comment: 5 pages, no figure

    Energy Distribution of a Charged Regular Black Hole

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    We calculate the energy distribution of a charged regular black hole by using the energy-momentum complexes of Einstein and M{\o}ller.Comment: 6 pages, no figure

    Energy and momentum of cylindrical gravitational waves. II

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    Recently Nathan Rosen and the present author obtained the energy and momentum densities of cylindrical gravitational waves in Einstein's prescription and found them to be finite and reasonable. In the present paper we calculate the same in prescriptions of Tolman as well as Landau and Lifshitz and discuss the results.Comment: 8 pages, LaTex, To appear in Pramana- J. Physic

    Energy Associated with Schwarzschild Black Hole in a Magnetic Universe

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    In this paper we obtain the energy distribution associated with the Ernst space-time (geometry describing Schwarzschild black hole in Melvin's magnetic universe) in Einstein's prescription. The first term is the rest-mass energy of the Schwarzschild black hole, the second term is the classical value for the energy of the uniform magnetic field and the remaining terms in the expression are due to the general relativistic effect. The presence of the magnetic field is found to increase the energy of the system.Comment: RevTex, 8 pages, no figures, a few points are clarified, to appear in Int. J. Mod. Phys. A. This paper is dedicated to Professor G. F. R. Ellis on the occasion of his 60th birthda

    Energy associated with charged dilaton black holes

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    It is known that certain properties of charged dilaton black holes depend on a free parameter β\beta which controls the strength of the coupling of the dilaton to the Maxwell field. We obtain the energy associated with static spherically symmetric charged dilaton black holes for arbitrary value of the coupling parameter and find that the energy distribution depends on the value of β\beta. With increasing radial distance, the energy in a sphere increases for β=0\beta = 0 as well as for β1\beta 1, and remains constant for β=1\beta = 1. However, the total energy turns out to be the same for all values of β\beta.Comment: singlespaced 7 pages, LaTex, no figures, misprints corrected, to appear in Int. J. Mod. Phys.

    Janis-Newman-Winicour and Wyman solutions are the same

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    We show that the well-known most general static and spherically symmetric exact solution to the Einstein-massless scalar equations given by Wyman is the same as one found by Janis, Newman and Winicour several years ago. We obtain the energy associated with this spacetime and find that the total energy for the case of the purely scalar field is zero.Comment: 9 pages, LaTex, no figures, misprints corrected, to appear in Int. J. Mod. Phys.

    M{\o}ller Energy for the Kerr-Newman metric

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    The energy distribution in the Kerr-Newman space-time is computed using the M{\o}ller energy-momentum complex. This agrees with the Komar mass for this space-time obtained by Cohen and de Felice. These results support the Cooperstock hypothesis.Comment: 8 pages, 1 eps figure, RevTex, accepted for publication in Mod. Phys. Lett.

    Strong gravitational lensing by a rotating non-Kerr compact object

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    We study the strong gravitational lensing in the background of a rotating non-Kerr compact object with a deformed parameter ϵ\epsilon and an unbound rotation parameter aa. We find that the photon sphere radius and the deflection angle depend sharply on the parameters ϵ\epsilon and aa. For the case in which the black hole is more prolate than a Kerr black hole, the photon sphere exists only in the regime ϵϵmax\epsilon\leq\epsilon_{max} for prograde photon. The upper limit ϵmax\epsilon_{max} is a function of the rotation parameter aa. As ϵ>ϵmax\epsilon>\epsilon_{max}, the deflection angle of the light ray closing very to the naked singularity is a positive finite value, which is different from those in both the usual Kerr black hole spacetime and in the rotating naked singularity described by Janis-Newman-Winicour metric. For the oblate black hole and the retrograde photon, there does not exist such a threshold value. Modelling the supermassive central object of the Galaxy as a rotating non-Kerr compact object, we estimated the numerical values of the coefficients and observables for gravitational lensing in the strong field limit.Comment: 16 pages, 10 figures. The corrected version to be appeared in Phys. Rev.

    Energy Distribution in Melvin's Magnetic Universe

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    We use the energy-momentum complexes of Landau and Lifshitz and Papapetrou to obtain the energy distribution in Melvin's magnetic universe. For this space-time we find that these definitions of energy give the same and convincing results. The energy distribution obtained here is the same as we obtained earlier for the same space-time using the energy-momentum complex of Einstein. These results uphold the usefulness of the energy-momentum complexes.Comment: 8 pages, RevTex, no figure
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