Physically motivated ansatz for the Kerr spacetime

TL;DR

The paper proposes a new physically motivated ansatz for the Kerr spacetime using a non-orthonormal tetrad based on oblate spheroidal coordinates, simplifying the derivation of the Kerr solution.

Contribution

It introduces a novel ansatz that separates mass and rotation effects in the Kerr metric using a simple, mass-independent flat space tetrad in oblate spheroidal coordinates.

Findings

Mass dependence isolated in the metric component g_AB

Non-orthonormal tetrad chosen as a mass-independent flat Minkowski space

Simplifies the derivation and understanding of the Kerr solution

Abstract

Despite some 60 years of work on the subject of the Kerr rotating black hole there is as yet no widely accepted physically based and pedagogically viable ansatz suitable for deriving the Kerr solution without significant computational effort. (Typically involving computer-aided symbolic algebra.) Perhaps the closest one gets in this regard is the Newman-Janis trick; a trick which requires several physically unmotivated choices in order to work. Herein we shall try to make some progress on this issue by using a non-ortho-normal tetrad based on oblate spheroidal coordinates to absorb as much of the messy angular dependence as possible, leaving one to deal with a relatively simple angle-independent tetrad-component metric. That is, we shall write $g_{ab} = g_{AB} \; e^A{}_a\; e^B{}_b$ seeking to keep both the tetrad-component metric $g_{AB}$ and the non-ortho-normal co-tetrad $e^A{}_a$ relatively simple but non-trivial. We shall see that it is possible to put all the mass dependence into $g_{AB}$, while the non-ortho-normal co-tetrad $e^A{}_a$ can be chosen to be a mass-independent representation of flat Minkowski space in oblate spheroidal coordinates: $(g_\mathrm{Minkowski})_{ab} = \eta_{AB} \; e^A{}_a\; e^B{}_b$. This procedure separates out, to the greatest extent possible, the mass dependence from the rotational dependence, and makes the Kerr solution perhaps a little less mysterious.