Generating Einstein-scalar solutions

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Generating Einstein-scalar solutions D C Robinson Mathematics Department King s College London Strand London WC2R 2LS United Kingdom david.c.robinson@kcl.ac.uk July 0, 2006 Abstract: In this comment on a recent paper by Dunajski a method of generating solutions of the Einstein-scalar field equations from Einstein metrics is presented. Two spherically symmetric examples are presented. 1

In a recent paper,[1], Maciej Dunajski used the standard Kaluza-Klein reduction ansatz from five to four dimensions to construct new four-metrics which satisfy the Einstein-Maxwell-Dilaton field equations from Einstein four-metrics. The aim of this comment is to point out a way in which Lorentzian solutions of the Einstein-scalar equations can be similarly constructed from any known Lorentzian Einstein four-metric which admits a non-null hypersurface orthogonal Killing vector field. The construction follows the same main lines as Dunajski s but differs in some details. It leads to Einstein-scalar four metrics which do not necessarily possess continuous isometries. The zero rest-mass scalar fields are minimally coupled in the standard (non-phantom) way and the cosmological constant is zero. First let ds 2 (4) be the line element of a Lorentzian four-metric on a four dimensional manifold M, with signature (,1), which admits a hyper-surface orthogonal, non-null killing vector field K. It is assumed to be Einstein so that it satisfies the equations G αβ = Λg αβ. (1) In coordinates adapted to K the line element takes the form ds 2 (4) = g ij dx i dx j + V (dx 4 ) 2, (2) where K = / x 4 and / x 4 (g ij ) = / x 4 V = 0. Two cases need to be considered. (i) The function V <0, the signature of g ij is Euclidean and K is time-like. (ii) The function V > 0,the signature of g ij is (2,1) and K is space-like. In the first case when V is replaced by V the resulting Riemannian metric also satisfies Equation (1) and it this metric that is employed in the following construction. To emphasize this let V = U 2. Now it is known that any Einstein four-metric on M can be used to construct a Ricci flat five-metric on M R, [2]. Here the Ricci- flat five-metric can be written as ds 2 (5) = ɛ(dx 0 ) 2 + (ax 0 + b) 2 g ij dx i dx j + (ax 0 + b) 2 U 2 (dx 4 ) 2. () Here ɛ = 1 and a and b are constants with a 2 = ɛλ/. (4) Consequently ɛ and a non-zero Λ must have the same sign. The fivemetric is Lorentzian, as is chosen to be the case here, when ɛ = 1 in case (i) and ɛ = 1 in case (ii). 2

Now, following Dunajski, this line element, with hypersurface orthogonal Killing vector field / x 4, is identified with the standard form used in the Kaluza-Klein reduction, that is with the metric form ds 2 (5) = exp( 2Φ/ )ds 2 + exp(4φ/ )(dx 4 ) 2. (5) This leads to the identification of a new four-metric ds 2 = ɛ U(ax 0 + b) (dx 0 ) 2 + U(ax 0 + b) g ij dx i dx j, (6) and a scalar field Φ = 2 ln U(ax 0 + b). (7) With this identification it follows automatically that the new Lorentzian four-metric and scalar field satisfy the Einstein-scalar field equations, where the zero rest-mass scalar field is conventionally and minimally coupled. An Einstein-scalar solution obtained in this way, and the original Einstein metric are both contained in a Ricci flat five-metric and are extracted from it via different fibrations of the five manifold. When Λ is non-zero the final four-metric does not necessarily admit a Killing vector field. Henceforth this is the case that will be considered and it will then simplify the formulae if the new coordinate y = ln ax 0 + b is introduced. It then follows that the five-metric is given by the new four-metric is ds 2 (5) = exp(2y)[ Λ dy2 + g ij dx i dx j + U 2 (dx 4 ) 2 ], (8) ds 2 = U exp(y)[ Λ dy2 + g ij dx i dx j ], (9) and the scalar field is Φ = (y + ln U ). (10) 2 Simple illustrative applications of this procedure are to the Kottler and Narai metrics with non-zero Λ. First consider the Kottler metric, [], in the static patch ds 2 (4) = U 2 dt 2 + U 2 dr 2 + r 2 dω 2, (11) where

U 2 = (1 2m r Λr2 ) > 0, (12) dω 2 = dθ 2 + sin 2 θdϕ 2. These coordinates are adapted to the two hypersurface orthogonal Killing vector fields / t and / ϕ. It will suffice here to exhibit the procedure using case (i) above with x 4 = t. In this case the starting point is chosen to be the Schwarzschild-anti-de Sitter family with Λ < 0. From the above results, and writing y = T, it follows immediately that the spherically symmetric Einstein-scalar solutions generated from this family are given by ds 2 = 1 2m r Λr2 and 1/2 Φ = exp(t)[ Λ dt 2 + 1 2m r Λr2 1 dr 2 + r 2 dω 2 ], (1) 2 [T + 1 2 ln 1 2m r Λr2 ]. (14) Next take as starting Einstein four-metrics the Narai family, [4], in the form [5] ds 2 (4) = Λ 1 [cosh 2 tdr 2 + dω 2 dt 2 ]. (15) with Λ > 0. These coordinates are adapted to the Killing vector fields / r and / ϕ. By applying the general procedure as in case (ii) above, with x 4 = r and y = R, the spherically symmetric Einstein-scalar solutions ds 2 = exp(r) cosh t [ dt 2 + dr 2 + dω 2 ], (16) Λ /2 t Φ = [R + ln(cosh )], (17) 2 Λ1/2 are generated from the Nariai metrics. The solution generating method discussed in this paper is an addition to earlier methods of generating Einstein-scalar solutions from known solutions. Examples of such methods can be found in reference [6]. Acknowledgement I would like to thank Maciej Dunajski for his comments and for suggesting the introduction of the coordinate y. 4

References [1] Dunajski, M. (2006) Einstein-Maxwell-Dilaton metrics from threedimensional Einstein-Weyl structures, Class. Quantum Grav. 2, 28-2840. [2] Lidsey, J.E., Romero, C., Tavakol, R., Rippl, S. (1997) On Applications of Campbell s Embedding Theorem, Class. Quantum Grav. 14, 865-879. [] Kottler, F. (1918) Uber die physikalischen Grundlagen der Einsteinschen Gravitationstheorie, Annalen der Physik 56, 401-462. [4] Nariai, H. (1951) On a new cosmological solution of Einstein s field equations of gravitation, Sci. Rep. Tohoku Univ. Ser. I 5, 62-67. [5] Bousso, R. (200) Adventures in de Sitter space, in The Future of Theoretical Physics and Cosmology: Celebrating Stephen Hawking s 60 th birthday, eds. G.W. Gibbons, E.P.S. Shellard, S.J. Rankin (Cambridge University Press, Cambridge). [6] Fonarev, O.A. (1995) Exact Einstein scalar field solutions for formation of black holes in a cosmological setting, Class. Quantum Grav. 12, 179-1752. 5

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