Search This Website

Thursday, 18 August 2016

In this August 27, 2015 illustration released by NASA, a binary black hole, Markarian 231, found in the centre of the nearest quasar host galaxy to Earth is seen. in 1974, Stephen Hawking suggested particles, that are now called Hawking radiation, could escape black holes.


         Stephen Hawking’s prediction about black holes observed in lab


                     In this August 27, 2015 illustration released by NASA, a binary black hole, Markarian 231, found in the centre of the nearest quasar host galaxy to Earth is seen. in 1974, Stephen Hawking suggested particles, that are now called Hawking radiation, could escape black holes.

.


Scientists who created a virtual black hole in the lab claim to have observed for the first time a phenomenon predicted by British physicist Stephen Hawking more than 30 years ago according to which some particles can escape black holes.
Jeff Steinhauer, a physicist at the Israel Institute of Technology built a virtual black hole in the lab in order to prove that Hawking’s theory of radiation emanating from black holes is correct — though his experiments are based on sound, rather than light.
Steinhauer said that he observed the quantum effects of Hawking radiation in his lab as part of a virtual black hole — which, if proven to be true, will be the first time it has ever been achieved.
For many years, scientists believed that nothing could ever escape from a black hole — not even light.
However, in 1974, Stephen Hawking suggested particles, that are now called Hawking radiation, could escape black holes.
According to him if a particle and its antimatter appeared spontaneously at the edge of a black hole, one of the pair might be pulled into the black hole while the other escaped, taking some of the energy from the black hole with it.
This would explain why black holes grow smaller and eventually disappear.
However, since such emissions are feeble, no one has been able to measure Hawking radiation. Researchers have instead tried to build virtual black holes in labs to test the theory.
Steinhauer’s experiment consisted of creating an entangled pair of phonons sitting inside a bit of liquid that had been forced to move very fast and then observing the action as one of the pair was pulled away as the liquid began to move faster than the speed of sound, while the other escaped, ‘Phys.org’ reported.
The fluid was a Bose-Enistein condensate of rubidium-87 atoms. After repeating the experiment 4,600 times, Steinhauer became convinced that the particles were entangled, a necessity for a Hawking radiation analogue.
The research was published in the journal Nature Physics.

No comments:

Post a Comment