On the multipole moments of a rigidly rotating fluid body

Abstract: Based on numerical simulations and analytical calculations we formulate a new conjecture concerning the multipole moments of a rigidly rotating fluid body in equilibrium. The conjecture implies that the exterior region of such a fluid is not described by the Kerr metric.

“…We also mention that, according to our experience, the exterior spacetime of a uniformly rotating fluid body is never described by the Kerr metric-except for the black hole limit e V 0 → 0 . As long as e V 0 = 0, all "higher" multipole moments (beyond M and J ) always seem to be greater than those of the corresponding Kerr spacetime [29].…”

On the black hole limit of rotating discs and rings

“…We also mention that, according to our experience, the exterior spacetime of a uniformly rotating fluid body is never described by the Kerr metric-except for the black hole limit e V 0 → 0 . As long as e V 0 = 0, all "higher" multipole moments (beyond M and J ) always seem to be greater than those of the corresponding Kerr spacetime [29].…”

On the black hole limit of rotating discs and rings

“…12 An interesting general feature of the exterior field of uniformly rotating perfect fluid bodies seems to be that all gravitational multipole moments beyond M and J, in particular the quadrupole moment, are greater than or equal to the corresponding moments of the Kerr metric with the same mass and angular momentum. 13 The equality holds (presumably only) in the case of a "black hole limit" where all multipole moments become precisely those of the extreme Kerr metric. 14 This will be discussed in more detail in the next section.…”

Relativistic Figures of Equilibrium: From Maclaurin Spheroids to Kerr Black Holes