For decades, scientists have wrestled with a complex mystery of physics: can a huge amount of energy, theoretically generated by turning a black hole, ever be applied by a human hand?
If the societies of the future were somehow able to contain this magnificent feat, the power supply of distant galactic civilizations would probably be guaranteed – and now scientists have a new explanation of how such a foreign extraction could one day be possible.
“Black holes are usually surrounded by a hot ‘soup’ of plasma particles that have a magnetic field,” explains Luke Comiso, an astrophysicist at Columbia University.
“Our theory shows that when magnetic field lines are disconnected and reconnected, only properly, they can accelerate plasma particles in negative gies and large amounts of black hole energy can be racked.”
Comiso’s new work – Felipe A., a physicist from Chile’s Universidad Adolfo Ibiz. Co-written by Assenjo – Spinning provides a new prism for a glimpse of how energy radiation extraction from black holes can work.
Given their extreme mass, it is natural to assume that even black holes have a lot of energy. Unfortunately, it is all locked under a slippery slope of space-time.
In the position where the mass rotates, it is possible to immerse the thumb in this abundant energy pool, pulling along the opacity of space.
Ox Xford The famous university of physicist and mathematician Roger Penrose suggests an ingenious method. In what became known as the Penrose process, the occurrence of a black hole could theoretically be an energy release from a region outside the horizon, called the ergosphere, within which space-time is changed by the effects of black hole rotation.
Penrose’s calculations suggest that if a particle splits into two parts within the ergosphere, one falls on the event horizon and the other exits the gravitational pull of the black hole, the energy received by the escaping object would be theoretically workable, if practically. Is impossible.
This popular idea was experimentally tested in a paper published by scientists months ago, but spinning is not the only suggestion to increase the magnitude of black holes.
Quantum King radiation is another method around quantum mechanical emissions, similarly known as the B-landford-Znajack process, in which electromagnetism can be electromagnetically racted through a magnetic field around a black hole.
In the analysis of Comiso and Essenjo, magnetism also plays a central role – in particular, as the lines of the magnetic field break and reconnect within the ergosphere – but it also recalls some of the thinking of the Penrose process.
As magnetic attachments occur outside the event horizon – splitting plasma particles accelerate to reach the speed of light in two different directions – one plasma current can fall within the event horizon, while the other is released.
From the point of view of black holes, the falling particles are filled with negative energy. Outside the black hole, the emitted particle will have a positive energy radiation that can work.
By this method, avoiding plasma currents with top-up energy radiation can theoretically serve as a virtually unlimited source of energy free energy radiation, as long as the black hole absorbs negative energy radiation plasma, i.e..
“We have calculated that the plasma energy process can reach 150 percent efficiency, which is much higher than any power plant operating on earth.”
“Achieving more than 100 percent efficiency is possible because black holes are leaking energy, which is given free to the plasma emanating from the black hole.”
While it may not be possible for us to use this energy energy product in a practical way at some point, it does not mean that it is completely useless.
From an astronomical point of view, the phenomenon could be the power that powers black hole flares – blocked radiation energy in space represents a huge release of radiation.
The authors write, “Unlike the landford-Znajack process, in which the extraction of circulating energy radiation is obtained by a pure electromagnetic mechanism, the energy radiation extraction method described here requires the inertia of non-zero particles,” the authors write.
“This method is also different from the original Panorama process, as it requires the dispersion of magnetic energy radiation to produce negative energy radiation particles.
These findings are reported Physical Review d.