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(Top) 1 Rotation 2 Radial pull 3 Ergosphere size 4 References 5 Further reading 6 External links

Ergosphere

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At the ergospheres (shown here in violet for the outer and red for the inner one), the temporal metric coefficient g_tt becomes negative, i.e., acts like a purely spatial metric component. Consequently, timelike or lightlike worldlines within this region must co-rotate with the inner mass. Cartesian projection, equatorial perspective.^[1]

Inastrophysics, the ergosphere is a region located outside a rotating black hole's outer event horizon. Its name was proposed by Remo Ruffini and John Archibald Wheeler during the Les Houches lectures in 1971 and is derived from Ancient Greek ἔργον (ergon) 'work'. It received this name because it is theoretically possible to extract energy and mass from this region. The ergosphere touches the event horizon at the poles of a rotating black hole and extends to a greater radius at the equator. A black hole with modest angular momentum has an ergosphere with a shape approximated by an oblate spheroid, while faster spins produce a more pumpkin-shaped ergosphere. The equatorial (maximal) radius of an ergosphere is the Schwarzschild radius, the radius of a non-rotating black hole. The polar (minimal) radius is also the polar (minimal) radius of the event horizon which can be as little as half the Schwarzschild radius for a maximally rotating black hole.^[2]

Rotation[edit]

As a black hole rotates, it twists spacetime in the direction of the rotation at a speed that decreases with distance from the event horizon.^[3] This process is known as the Lense–Thirring effectorframe-dragging.^[4] Because of this dragging effect, an object within the ergosphere cannot appear stationary with respect to an outside observer at a great distance unless that object were to move at faster than the speed of light (an impossibility) with respect to the local spacetime. The speed necessary for such an object to appear stationary decreases at points further out from the event horizon, until at some distance the required speed is negligible.

The set of all such points defines the ergosphere surface, called ergosurface. The outer surface of the ergosphere is called the static surfaceorstatic limit. This is because world lines change from being time-like outside the static limit to being space-like inside it.^[5] It is the speed of light that arbitrarily defines the ergosphere surface. Such a surface would appear as an oblate that is coincident with the event horizon at the pole of rotation, but at a greater distance from the event horizon at the equator. Outside this surface, space is still dragged, but at a lesser rate.^{[citation needed]}

Radial pull[edit]

Animation: A test particle approaching the ergosphere in the retrograde direction is forced to change its direction of motion (inBoyer–Lindquist coordinates).

A suspended plumb, held stationary outside the ergosphere, will experience an infinite/diverging radial pull as it approaches the static limit. At some point it will start to fall, resulting in a gravitomagnetically induced spinward motion. An implication of this dragging of space is the existence of negative energies within the ergosphere.

Since the ergosphere is outside the event horizon, it is still possible for objects that enter that region with sufficient velocity to escape from the gravitational pull of the black hole. An object can gain energy by entering the black hole's rotation and then escaping from it, thus taking some of the black hole's energy with it (making the maneuver similar to the exploitation of the Oberth effect around "normal" space objects).

This process of removing energy from a rotating black hole was proposed by the mathematician Roger Penrose in 1969 and is called the Penrose process.^[6] The maximal amount of energy gain possible for a single particle via this process is 20.7% in terms of its mass equivalence,^[7] and if this process is repeated by the same mass, the theoretical maximal energy gain approaches 29% of its original mass-energy equivalent.^[8] As this energy is removed, the black hole loses angular momentum, and thus the limit of zero rotation is approached as spacetime dragging is reduced^{[citation needed]}. In the limit, the ergosphere no longer exists. This process is considered a possible explanation for a source of energy of such energetic phenomena as gamma-ray bursts.^[9] Results from computer models show that the Penrose process is capable of producing the high-energy particles that are observed being emitted from quasars and other active galactic nuclei.^[10]

Ergosphere size[edit]

The size of the ergosphere, the distance between the ergosurface and the event horizon, is not necessarily proportional to the radius of the event horizon, but rather to the black hole's gravity and its angular momentum. A point at the poles does not move, and thus has no angular momentum, while at the equator a point would have its greatest angular momentum. This variation of angular momentum that extends from the poles to the equator is what gives the ergosphere its oblate shape. As the mass of the black hole or its rotation speed increases, the size of the ergosphere increases as well.^[11]

References[edit]

^ Visser, Matt (15 Jan 2008). "The Kerr spacetime: A brief introduction". p. 35. arXiv:0706.0622 [gr-qc].

^ Griest, Kim (26 February 2010). "Physics 161: Black Holes: Lecture 22" (PDF). Archived (PDF) from the original on 2012-04-03. Retrieved 2011-10-19.

^ Misner 1973, p. 879.

^ Darling, David. "Lense-Thiring Effect". Archived from the original on 2009-08-11.

^ Misner 1973, p. 879.

^ Bhat, Manjiri; Dhurandhar, Sanjeev; Dadhich, Naresh (10 January 1985). "Energetics of the Kerr–Newman Black Hole by the Penrose Process" (PDF). Journal of Astrophysics and Astronomy. 6 (2): 85–100. Bibcode:1985JApA....6...85B. doi:10.1007/BF02715080. S2CID 53513572.

^ Chandrasekhar, p. 369.

^ Carroll, p. 271.

^ Nagataki, Shigehiro (28 June 2011). "Rotating BHs as Central Engines of Long GRBs: Faster is Better". Publications of the Astronomical Society of Japan. 63: 1243–1249. arXiv:1010.4964. Bibcode:2011PASJ...63.1243N. doi:10.1093/pasj/63.6.1243. S2CID 118666120.

^ Kafatos, Menas; Leiter, D. (1979). "Penrose pair production as a power source of quasars and active galactic nuclei". The Astrophysical Journal. 229: 46–52. Bibcode:1979ApJ...229...46K. CiteSeerX 10.1.1.924.9607. doi:10.1086/156928.

^ Visser, Matt (1998). "Acoustic black holes: horizons, ergospheres, and Hawking radiation". Classical and Quantum Gravity. 15 (6): 1767–1791. arXiv:gr-qc/9712010. Bibcode:1998CQGra..15.1767V. doi:10.1088/0264-9381/15/6/024. S2CID 5526480.

External links[edit]

v t e Black holes
Outline
Types	BTZ black hole Schwarzschild Rotating Charged Virtual Kugelblitz Supermassive Primordial Direct collapse Rogue Malament–Hogarth spacetime
Size	Micro Extremal Electron Hawking star Stellar Microquasar Intermediate-mass Supermassive Active galactic nucleus Quasar LQG Blazar OVV Radio-Quiet Radio-Loud
Formation	Stellar evolution Gravitational collapse Neutron star Related links Tolman–Oppenheimer–Volkoff limit White dwarf Related links Supernova Micronova Hypernova Related links Gamma-ray burst Binary black hole Quark star Supermassive star Quasi-star Supermassive dark star X-ray binary
Properties	Astrophysical jet Gravitational singularity Ring singularity Theorems Event horizon Photon sphere Innermost stable circular orbit Ergosphere Penrose process Blandford–Znajek process Accretion disk Hawking radiation Gravitational lens Microlens Bondi accretion M–sigma relation Quasi-periodic oscillation Thermodynamics Bekenstein bound Bousso's holographic bound Immirzi parameter Schwarzschild radius Spaghettification
Issues	Black hole complementarity Information paradox Cosmic censorship ER = EPR Final parsec problem Firewall (physics) Holographic principle No-hair theorem
Metrics	Schwarzschild (Derivation) Kerr Reissner–Nordström Kerr–Newman Hayward
Alternatives	Nonsingular black hole models Black star Dark star Dark-energy star Gravastar Magnetospheric eternally collapsing object Planck star Q star Fuzzball Geon
Analogs	Optical black hole Sonic black hole
Lists	Black holes Most massive Nearest Quasars Microquasars
Related	Outline of black holes Black Hole Initiative Black hole starship Black holes in fiction Big Bang Big Bounce Compact star Exotic star Quark star Preon star Gravitational waves Gamma-ray burst progenitors Gravity well Hypercompact stellar system Membrane paradigm Naked singularity Population III star Supermassive star Quasi-star Supermassive dark star Rossi X-ray Timing Explorer Superluminal motion Timeline of black hole physics White hole Wormhole Tidal disruption event Planet Nine
Notable	Cygnus X-1 XTE J1650-500 XTE J1118+480 A0620-00 SDSS J150243.09+111557.3 Sagittarius A* Centaurus A Phoenix Cluster PKS 1302-102 OJ 287 SDSS J0849+1114 TON 618 MS 0735.6+7421 NeVe 1 Hercules A 3C 273 Q0906+6930 Markarian 501 ULAS J1342+0928 PSO J030947.49+271757.31 P172+18 AT2018hyz Swift J1644+57
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