Taub–NUT space

The Taub–NUT metric is an exact solution to Einstein's equations. It may be considered a first attempt in finding the metric of a spinning black hole. It is sometimes also used in homogeneous but anisotropic cosmological models formulated in the framework of general relativity.

The underlying Taub space was found by, and extended to a larger manifold by , whose initials form the "NUT" of "Taub–NUT".

Taub's solution is an empty space solution of Einstein's equations with topology R×S3 and metric (or equivalently line element)
 * $$g =-dt^2/U(t) + 4l^2U(t)(d\psi+ \cos\theta d\phi)^2+(t^2+l^2)(d\theta^2+(\sin\theta)^2d\phi^2)$$

where
 * $$U(t)=\frac{2mt+l^2-t^2}{t^2+l^2}$$

and m and l are positive constants.

Taub's metric has coordinate singularities at $$U=0, t=m+(m^2+l^2)^{1/2}$$, and Newman, Tamburino and Unti showed how to extend the metric across these surfaces.

When Roy Kerr developed the Kerr metric for spinning black holes in 1963, he ended up with a four-parameter solution, one of which was the mass and another the angular momentum of the central body. One of the two other parameters was the NUT-parameter, which he threw out of his solution because he found it to be nonphysical since it caused the metric to be not asymptotically flat, while other sources interpret it either as a gravomagnetic monopole parameter of the central mass, or a twisting property of the surrounding spacetime.

A simplified 1+1-dimensional version of the Taub–NUT spacetime is the Misner spacetime.