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In this work a new asymptotically flat solution of the coupled Einstein-Born- Infeld equations for a static spherically symmetric space-time is obtained.

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Presentation on theme: "In this work a new asymptotically flat solution of the coupled Einstein-Born- Infeld equations for a static spherically symmetric space-time is obtained."— Presentation transcript:

1 In this work a new asymptotically flat solution of the coupled Einstein-Born- Infeld equations for a static spherically symmetric space-time is obtained. When the intrinsic mass is zero the resulting spacetime is regular everywhere, in the sense given by B. Hoffmann and L. Infeld in 1937, and the Einstein-Born- Infeld theory leads to the identification of the gravitational with the electromagnetic mass. This means that the metric, the electromagnetic field and their derivatives have not discontinuities in all the manifold. In particular, there are not conical singularities at the origin, in contrast to well known monopole solution studied by B. Hoffmann in 1935. The lack of uniqueness of the action function in Non-Linear-Electrodynamics is discussed.

2

3 Born (1934)

4 When r→0 Hoffmann (1935)

5

6 where

7 → The solution The line element

8 Function Y(r) for the set of parameters r 0 =1, a=-0.9, m=1, n=3

9 The magnetic case The electric field

10 From The interval takes the form

11 for The effective mass and charge Gravitational massElectromagnetic mass 

12 Asymptotic behavior near the origin

13

14

15 Concluding remarks In this report a new exact solution of the Einstein–Born–Infeld equations for a static spherically symmetric monopole is presented. The general behavior of the geometry is strongly modified according to the value that r0 takes ( Born–Infeld radius) and three new parameters: a, m, and n. The fundamental feature of this solution is the lack of conical singularities at the origin when −1 1. In particular, for m=1 and n=3, with the parameter a in the range given above and the intrinsic mass of the system M being zero, the strong regularity conditions given by Hoffmann and Infeld hold in all the space–time. For the set of values for the above-given parameters, the solution is asymptotically flat, free of singularities in the electric field, metric, energy–momentum tensor and their derivatives (with derivative values zero for r ! 0); and the electromagnetic mass (ADM) of the system is twice that of the electromagnetic mass of other well-known solutions for the Einstein–Born-Infeld monopole. The electromagnetic mass M el asymptotically is necessarily positive, which was not the case in the Schwarzschild line element. This solution has a surprising similitude with the metric for the global monopole in general relativity given by Bronnikov et al. [JETP 95, 392 (2002)]in the sense that the physics of the problem has a correct description only by means of a new radial function Y(r). Because the metric is regular ( g tt =−1, at r=0 and at r=  ), its derivative ( that is proportional to the force in Newtonian approximation ) must change sign. In Einstein–Born–Infeld theory with this new static solution, it is interesting to note that although this force is attractive for distances of the order r 0  r, it is actually repulsive for very small r.

16 References M. Born and L. Infeld, Proc. R. Soc. London 144, 425 ( 1934 ). B. Hoffmann, Phys. Rev. 47, 877 ( 1935 ). B. Hoffmann and L. Infeld, Phys. Rev. 51, 765 ( 1937 ). M. Demianski, Found. Phys. 16, 187 ( 1986 ). D. Harari and C. Lousto, Phys. Rev. D 42, 2626 ( 1990 ). M. Barriola and A. Vilenkin, Phys. Rev. Lett. 63, 341 ( 1989 ). L. D. Landau and E. M. Lifshitz, Teoria Clasica de los Campos s( Reverte, Buenos Aires, 1974), p. 574. C. Misner, K. Thorne, and J. A. Wheeler, Gravitation ( Freeman, San Francisco, 1973 ), p. 474. M. Born, Proc. R. Soc. London 143, 411 ( 1934 ). R. Metsaev and A. Tseytlin, Nucl. Phys. B 293, 385 ( 1987 ). Yu. Stepanovsky, Electro-Magnitie Iavlenia 3, 427 ( 1988 ). D. J. Cirilo Lombardo, Master thesis, Universidad de Buenos Aires, Argentina, 2001. S. Chandrasekhar, The Mathematical Theory of Black Holes ( Oxford University Press, New York, 1992 ). D. Kramer et al., Exact Solutions of Einstein’s Field Equations ( Cambridge University Press, Cambridge, 1980 ). A. S. Prudnikov, Yu. Brychov, and O. Marichev, Integrals and Series ( Gordon and Breach, New York, 1986 ). K. A. Bronnikov, B. E. Meierovich, and E. R. Podolyak, JETP 95, 392 ( 2002 ). D. J. Cirilo Lombardo, Preprint JINR-E2-2003-221.13

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