Abstract
Some new results on the boost-rotation symmetric spacetimes representing pairs of rotating charged objects accelerated in opposite directions are summarized. A particular attention is paid to (a) the Newtonian limit analyzed using the Ehlers frame theory and (b) the special-relativistic limit of the C-metric. Starting from the new, simpler form of the rotating charged C-metric we also show how to remove nodal singularities and obtain a rotating charged black hole freely falling in an external electromagnetic field.
Access provided by Autonomous University of Puebla. Download conference paper PDF
Similar content being viewed by others
Keywords
- Boost-rotation Symmetry
- Special Relativistic Limit
- Newtonian Limit
- Asymptotically Flat
- Electromagnetic Field Vanishes
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
1 Boost-Rotation Symmetric Spacetimes
Boost-rotation/axial symmetric spacetimes are important explicit examples of exact solutions of Einstein field equations describing non-trivially moving sources of gravitational and electromagnetic field [1]. The only “initial” assumption that is made is the existence of two Killing vectors: boost Killing vector \({\xi ^{\mu }_B}\) whose orbits are hyperbolas and axial Killing vector \({\xi ^{\mu }_{\phi }}\) with closed circular orbits. The metric of a general electrovacuum rotating boost-rotation symmetric spacetime in global coordinates reads:
Functions \(\mu \), \(\nu \) and \(\varOmega \) depend on \(a=z^2-t^2\) and \(b=r^2\) only and are determined by the Ernst equations (basic consequence of the Einstein field equations under these symmetries) and the character of sources. The nonlinear Ernst equations are difficult to solve but if rotation \(\varOmega \) and electromagnetic field vanish, then the basic Einstein field equation reduces to the wave equation on an auxiliary flat spacetime \(\square \mu =0\), while \(\nu \) can be determined by quadrature.
The main features of the boost-rotation symmetric spacetimes are:
-
(a)
they describe uniformly accelerated sources;
-
(b)
are asymptotically flat at null infinity except, in general, at two its generators;
-
(c)
the hypersurfaces \(z^2=t^2\), where the boost Killing vector \({\xi ^\mu _B}\) is null, invariantly divide the spacetime into four quadrants (see Fig. 1),
-
(c1)
below the roof (reg. I and III)—locally Weyl metrics,
-
(c2)
above the roof (reg. II and IV)—locally Einstein-Rosen, or Gowdy metrics;
-
(c1)
-
(d)
are of algebraic type \(I\), in general; the C-metric, describing accelerated black holes, is of type \(D\);
-
(e)
are radiative with a non-vanishing news function;
-
(f)
along the axis of symmetry there are conical singularities in general—they can be interpreted as strings or struts that cause the acceleration.
2 Newtonian Limit
Newtonian limit of a relativistic spacetime greatly corroborates its physical interpretation. We perform the limit within the framework of the Ehlers frame theory (see [2] for more details and references). The key point is the causality constant \(\lambda =c^{-2}\) which becomes zero in the limit. To do the limit we have to choose a suitable set of observers and a naturally adapted coordinate system.
Using (1) with functions \(\mu \) and \(\nu \) known, we first introduce a shift of the coordinate origin by putting \(z=\zeta +\lambda ^{-1} g^{-1}\); otherwise the particles would “disappear” to infinity (see Fig. 2).
Our procedure then results in a classical point particle undergoing uniform acceleration, \(z=\frac{1}{2}gt^2\), which generates classical field described by the Newtonian gravitational potential \(\varPhi ={m}/{\sqrt{r^2+(z-\frac{1}{2}gt^2)^2}}\). This follows from the limit of explicit examples of these spacetimes [2].
Our results thus strongly support the physical significance of the boost-rotation symmetric spacetimes (in contrast to some previous conclusions [3] which made the limit in the regions \(\textit{II}\) and \(\textit{IV}\)).
3 The Rotating Charged C-Metric
The rotating charged C-metric is a special case of the boost-rotation symmetric spacetimes. It describes two rotating charged black holes. It can be written in the form
where A and \(a\) are parameters characterizing acceleration and rotation, the mass parameter M enters function \(\fancyscript{G}\) which is polynomial of the 4-th order; \(K_{\phi }\),\(K_{\tau }\) are suitable constants. It was recently factorized by Emparan, Hong and Teo. See [5] for details and references. The transformation between the forms (2) and (1) is explicitly known.
The flat spacetime limit (i.e. \(G\rightarrow 0\)) of the charged rotating C-metric can be shown to lead to an electromagnetic field of two counter-rotating bent charged discs undergoing uniform acceleration (see Fig. 3, and [4] for details).
4 Removing the Conical Singularities
The charged C-metric represents a pair of uniformly accelerated black holes with mass \(m\), charge \(q\) and acceleration \(A\). These can be “immersed” in an external electric field \(E\) using the appropriate generating technique by Ernst. (The field breaks the asymptotic flatness.) For a suitably chosen value of \(E\) the axis becomes regular everywhere. This is because by adding the external field we include the “physical” source of the acceleration in the solution—the electromagnetic force. Utilizing the new factorized form of the C-metric, Ernst’s simple “equilibrium condition” \(mA = qE\) valid for small accelerations is generalized to an arbitrary \(A\). See [5] where rotation is also included.
References
Bičák, J., Schmidt, B.: Asymptotically flat radiative space-times with boost-rotation symmetry: the general structure. Phys. Rev. D 40, 1827 (1989). doi:10.1103/PhysRevD.40.1827
Bičák, J., Kofroň, D.: The Newtonian limit of spacetimes for accelerated particles and black holes. Gen. Relativ. Gravit. 41, 153 (2009). doi:10.1007/s10714-008-0662-0
Lazkoz, R., Valiente Kroon, J.A.: The Newtonian limit of space-times describing uniformly accelerated particles. Proc. R. Soc. London, Ser. A 460, 995 (2004). doi:10.1098/rspa.2003.1172
Bičák, J., Kofroň, D.: Accelerating electromagnetic magic field from the C-metric. Gen. Relativ. Gravit. 41, 1981 (2009). doi:10.1007/s10714-009-0816-8
Bičák, J., Kofroň, D.: Rotating charged black holes accelerated by an electric field. Phys. Rev. D 82, 024006 (2010). doi:10.1103/PhysRevD.82.024006
Acknowledgments
We would like to acknowledge the support from the Czech Science Foundation by grant GAČR No. 14-37086G.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2014 Springer International Publishing Switzerland
About this paper
Cite this paper
Bičák, J., Kofroň, D. (2014). Variations on Spacetimes with Boost-Rotation Symmetry. In: Bičák, J., Ledvinka, T. (eds) Relativity and Gravitation. Springer Proceedings in Physics, vol 157. Springer, Cham. https://doi.org/10.1007/978-3-319-06761-2_33
Download citation
DOI: https://doi.org/10.1007/978-3-319-06761-2_33
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-06760-5
Online ISBN: 978-3-319-06761-2
eBook Packages: Physics and AstronomyPhysics and Astronomy (R0)