Abstract
We study how black hole entropy is generated and the role it plays in several highly dynamical processes: the decay of unstable black strings and ultraspinning black holes; the fusion of two rotating black holes; and the subsequent fission of the merged system into two black holes that fly apart (which can occur in dimension D ≥ 6, with a mild violation of cosmic censorship). Our approach uses the effective theory of black holes at D → ∞, but we expect our main conclusions to hold at finite D. Black hole fusion is highly irreversible, while fission, which follows the pattern of the decay of black strings, generates comparatively less entropy. In 2 → 1 → 2 black hole collisions an intermediate, quasi-thermalized state forms that then fissions. This intermediate state erases much of the memory of the initial states and acts as an attractor funneling the evolution of the collision towards a small subset of outgoing parameters, which is narrower the closer the total angular momentum is to the critical value for fission. Entropy maximization provides a very good guide for predicting the final outgoing states. Along our study, we clarify how entropy production and irreversibility appear in the large D effective theory. We also extend the study of the stability of new black hole phases (black bars and dumbbells). Finally, we discuss entropy production through charge diffusion in collisions of charged black holes.
Highlights
Introduction and summaryThe area theorem, or second law of black holes, has pervasive implications in all of black hole physics
How does the second law constrain the possible final states? Are there phenomena where it can provide more than bounds on allowed outcomes, for instance, indicating their likelihood, according to how much entropy they generate? Since the area of the event horizon can be computed outside stationary equilibrium, one may even study the mechanisms that drive its growth at different stages
We examine in detail the production of entropy — its total increase, and its generation localized in time and in space on the horizon — in processes where an unstable black hole decays and fissions, and in collisions where two black holes fuse into a single horizon
Summary
The area theorem, or second law of black holes, has pervasive implications in all of black hole physics. After fixing an overall scale by setting the total mass to one, the outgoing black holes are characterized by their spin parameter a, outgoing velocity u, and outgoing impact parameter b.5 We argue that these can be well predicted by considering three different constraints: 4These J and M are defined in the effective theory; the corresponding physical quantities are given in appendix D. Readers familiar with the large D effective theory of black holes and branes may be surprised that the entropy growth can be computed with its equations to leading order in the 1/D expansion This theory is known to exactly conserve the entropy of the system: the LO entropy current is divergence-free, and entropy generation is suppressed by a factor 1/D [7, 20].
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