Wiktionary
n. (context physics English) A region outside the event horizon of a rotating black hole in which space and time are distorted by shear forces.
Wikipedia
thumb|right|300px|In the ergosphere (shown here in light gray), the component g is 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. Coordinate system: Kerr-Schild, equatorial perspective. The ergosphere is a region located outside a rotating black hole. Its name proposed by Remo Ruffini and John Archibald Wheeler during the Les Houches lectures in 1971, is derived from the Greek word ergon, which means “work”. It received this name because it is theoretically possible to extract energy and mass from this region. The ergosphere has an oblate spheroidal shape that touches the event horizon at the poles of a rotating black hole and extends to a greater radius at the equator. The equatorial (maximum) radius of an ergosphere corresponds to the Schwarzschild radius of a non-rotating black hole; the polar (minimum) radius can be as little as half the Schwarzschild radius (the radius of a non rotating black hole) in the case that black hole is rotating maximally (at higher rotation rates the black hole could not have formed).
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. This process is known as the Lense-Thirring effect or frame-dragging. Because of this dragging effect, objects within the ergosphere can not appear stationary with respect to an outside observer at a great distance unless that object was 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 that of the speed of light. The set of all such points defines the ergosphere surface. The outer surface of the ergosphere is called the static surface or static limit. This is because world lines change from being time-like outside the static limit to being space-like inside it. 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.
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. 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. The maximum amount of energy gain possible for a single particle via this process is 20.7%, in terms of its mass equivalence, and if this process is repeated by the same mass the theoretical maximum energy gain approaches 29% of its original mass-energy equivalent. As this energy is removed, the black hole loses angular momentum, the limit of zero rotation is approached as spacetime dragging is reduced. 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. 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.
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 oblated shape. As the mass of the black hole or its rotation speed increases, the size of the ergosphere increases as well.
Usage examples of "ergosphere".
Object-Oriented Socialism had suffered a huge debt write-off, but they continued to do well on the strength of their subsidiary interests in ergosphere mining.
Searcher could exit the ergosphere along a path that pops out into another space-time, or another time in our own space.
Inside the ergosphere we would be constrained to rotate with the hole.
I want to flyby, clipping the ergosphere, and slingshot off the black hole.
Without spin, its event horizon expanded, filling up the equatorial belt where the ergosphere had been.
Likely they would slowly descend in a spiral orbit until they reached the singularity and oblivion, but here, near the top of the ergosphere, there was still a chance.
For a brief instant we were spinning with the ergosphere, and you could see the relative motion of the neighboring black holes out there.
From those motions, the ergosphere spin is opposite to our initial trajectory.
You shoot a particle into an ergosphere, opposite to the spin direction.
The only real progress was during the brief seconds when they were just above the edge of the ergosphere and again in normal space.
Sumio held his breath a lot during docking, and kept his secret to himself: once they were completely buried in the ergosphere, there would be no docking possible, and they would all die.
It was a gimbaled burn, two seconds for a dip into the ergosphere, followed by five seconds against the flow, a two second burn by the empty ship just before locking bolts exploded for separation.
The ergosphere had spit them out into a trajectory that nearly took them back to Cassandra I, but fell short, so they had to wait two days for Cassandra II.
The ergosphere was a rotating fat waist in he diagram, but ahead bulged something spitting light like an angry, etting sun.
Think of the ergosphere as a tight-stretched skin of space-time, across which waves wash.