Spin Self-Force

TL;DR

This paper investigates the effects of spin and charge self-force on bodies falling into Kerr-Newman black holes, deriving bounds on the self-force energy and analyzing implications for black hole area change and reversibility.

Contribution

It generalizes previous work by calculating the lower bound of self-force energy for spinning and charged bodies on Kerr-Newman black holes, including finite size and quadrupole effects.

Findings

Net spin self-force energy is at least S^2/8M^3 for uncharged bodies.

Finite size effects impose a lower bound on self-force energy at the horizon.

The results suggest a minimum self-force energy for charged and spinning bodies, affecting black hole thermodynamics.

Abstract

We consider the motion of charged and spinning bodies on the symmetry axis of a non-extremal Kerr-Newman black hole. If one treats the body as a test point particle of mass, $m$, charge $q$, and spin $S$, then by dropping the body into the black hole from sufficiently near the horizon, the first order area increase, $\delta A$, of the black hole can be made arbitrarily small, i.e., the process can be done in a ``reversible'' manner. At second order, there may be effects on the energy delivered to the black hole---quadratic in $q$ and $S$---resulting from (i) the finite size of the body and (ii) self-force corrections to the energy. Sorce and Wald have calculated these effects for a charged, non-spinning body on the symmetry axis of an uncharged Kerr black hole. We consider the generalization of this process for a charged and spinning body on the symmetry axis of a Kerr-Newman black hole, where the self-force effects have not been calculated. A spinning body (with negligible extent along the spin axis) must have a mass quadrupole moment $\gtrsim S^2/m$, so at quadratic order in the spin, we must take into account quadrupole effects on the motion. After taking into account all such finite size effects, we find that the condition $\delta^2 A \geq 0$ yields a nontrivial lower bound on the self-force energy, $E_{SF}$, at the horizon. In particular, for an uncharged, spinning body on the axis of a Kerr black hole of mass $M$, the net contribution of spin self-force to the energy of the body at the horizon is $E_{SF} \geq S^2/8M^3$, corresponding to an overall repulsive spin self-force. A lower bound for the self-force energy, $E_{SF}$, for a body with both charge and spin at the horizon of a Kerr-Newman black hole is given. This lower bound will be the correct formula for $E_{SF}$ if the dropping process can be done reversibly to second order.