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Monster Black Hole from Early Universe Found Twisting Space at Half the Speed of Light




The discovery by astronomers have used NASA's Chandra X-ray Observatory and the European Space Agency's (ESA's) XMM-Newton, that the black hole in RX J1131 is spinning at over half the speed of light suggests this black hole, observed at a distance of six billion light years, corresponding to an age about 7.7 billion years after the Big Bang, has grown via mergers, rather than pulling material in from different directions. Prior to the announcement of this work, the most distant black holes with direct spin estimates were located 2.5 billion and 4.7 billion light-years away. This monster black hole rotates at roughly half the speed of light twisting space as it turns. The fast-spin points to how galaxies, such as ours, grew larger billions of years ago.

"If the growth is chaotic, then the spin of the black hole heads toward zero," says astrophysicist Emanuele Berti of the University of Mississippi at Oxford. "In that case, the black hole acts like a top given random kicks from side to side, which rob it of energy to spin." But if the structure of a growing galaxy is orderly, with vast clouds of hydrogen gas and the occasional smaller black hole flowing into its center to feed the central black hole steadily, its spin will increase.

"We're seeing a very rapid spin, which points to a more coherent structure to early galaxies during their formation," says Nature study co-author Mark Reynolds of the University of Michigan. How the Milky Way and stars like our sun formed appear to be better explained by understanding this formation.

The ability to measure black hole spin over a large range of cosmic time should make it possible to directly study whether the black hole evolves at about the same rate as its host galaxy. The measurement of the spin of the RX J1131-1231 black hole is a major step along that path and demonstrates a technique for assembling a sample of distant supermassive black holes with current X-ray observatories. Black holes are defined by just two simple characteristics: mass and spin. While astronomers have long been able to measure black hole masses very effectively, determining their spins has been much more difficult.

In the past decade, astronomers have devised ways of estimating spins for black holes at distances greater than several billion light-years away, meaning we see the region around black hole as they were billions of years ago. However, determining the spins of these remote black holes involves several steps that rely on one another.

"We want to be able to cut out the middle man, so to speak, of determining the spins of black holes across the universe," said Rubens Reis of the University of Michigan in Ann Arbor, who led a paper describing this result that was published online Wednesday in the journal Nature.

Reis and his colleagues determined the spin of the supermassive black hole that is pulling in surrounding gas, producing an extremely luminous quasar known as RX J1131-1231 (RX J1131 for short). Because of fortuitous alignment, the distortion of space-time by the gravitational field of a giant elliptical galaxy along the line of sight to the quasar acts as a gravitational lens that magnifies the light from the quasar. Gravitational lensing, first predicted by Einstein, offers a rare opportunity to study the innermost region in distant quasars by acting as a natural telescope and magnifying the light from these sources.

"Because of this gravitational lens, we were able to get very detailed information on the X-ray spectrum – that is, the amount of X-rays seen at different energies – from RX J1131," said co-author Mark Reynolds also of Michigan. "This in turn allowed us to get a very accurate value for how fast the black hole is spinning."

The X-rays are produced when a swirling accretion disk of gas and dust that surrounds the black hole creates a multimillion-degree cloud, or corona near the black hole. X-rays from this corona reflect off the inner edge of the accretion disk. The strong gravitational forces near the black hole alter the reflected X-ray spectrum. The larger the change in the spectrum, the closer the inner edge of the disk must be to the black hole.

"We estimate that the X-rays are coming from a region in the disk located only about three times the radius of the event horizon, the point of no return for infalling matter," said Jon M. Miller of Michigan, another author on the paper. "The black hole must be spinning extremely rapidly to allow a disk to survive at such a small radius."

For example, a spinning black hole drags space around with it and allows matter to orbit closer to the black hole than is possible for a non-spinning black hole.

By measuring the spin of distant black holes researchers discover important clues about how these objects grow over time. If black holes grow mainly from collisions and mergers between galaxies, they should accumulate material in a stable disk, and the steady supply of new material from the disk should lead to rapidly spinning black holes. In contrast, if black holes grow through many small accretion episodes, they will accumulate material from random directions. Like a merry go round that is pushed both backwards and forwards, this would make the black hole spin more slowly.

The Daily Galaxy via Chandra Space Observatory, Nature.com, and National Geographic


Perhaps the mergers are bh to bh? That would indicate that some method of bh production is constant and agree with science that indicates bhs are found in the same place now and in deep time of 12 by ago. Then what happens when the bh reaches maturity? A singularity spits into a new bubble universe?
Maybe what happens is that the speed of the bh and its magnetic wrap create a time rift that allows the accumulated energy to 'tear time' with the result being a younger galaxy and gas clouds?

katesisco, that's some good thinking which I think the chalk board theorists should grab ahold of and release some new theory. Half C however isn't much of a time distortion as it may seem. Since C and time distortion are a hyperbolic function, that is, as C increases, time distortion increases MORE proportionately AS IT GOES ALONG, that is .5 C isn't the same time distortion arithmetic as .9 C time distortion, for it's not a straight line function of fractions of C adding up to a whole C. Dunno If I make myself clear here...apologies if not.

In a Popular Science article I think 12 years ago, that magazine had an article on how to distort time with a fast revolving magnetic field and it was measured in a lab..the revolutions were "relativistic", meaning a noted time distortion occurred.

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