Abstract
This article is an extended version of a presentation given at KOZWaves 2024: The 6th Australasian Conference on Wave Science, held in Dunedin, New Zealand.
Vries equation, which describes nonlinear water waves. Interestingly, the same methods can also be used to analyse equilibrium configurations in general relativity. An intriguing open problem is whether a relativistic 𝑛-body system can be in stationary equilibrium. Due to the nonlinear effect of spin–spin repulsion of rotating objects, and possibly considering charged bodies with additional electromagnetic repulsion, the existence of such unusual configurations remains a possibility. An important example is a (hypothetical) equilibrium configuration with 𝑛 aligned black holes. By studying a linear matrix problem equivalent to the Einstein equations for axisymmetric and stationary (electro-) vacuum spacetimes, we derive the most general form of the boundary data on the symmetry axis in terms of a finite number of parameters. In the simplest case 𝑛 = 1, this leads to a constructive uniqueness proof of the Kerr (–Newman) solution. For 𝑛 = 2 and vacuum, we obtain non-existence of stationary two-black-hole configurations. For 𝑛 = 2 with electrovacuum, and for larger 𝑛, it remains an open problem whether the well-defined finite solution families contain any physically reasonable solutions, i.e. spacetimes without anomalies such as naked singularities, magnetic monopoles, and struts.