Paradox Solved? How Information Can Escape from a Black Hole
Artist's concept of the MWC 656 system, which consists of a massive "Be" star and a companion black hole. The star rotates at very high speed, ejecting an equatorial disc of matter that is transferred to the black hole through an accretion disc.
Credit: Gabriel Pérez Díaz, Servicio MultiMedia (IAC)

Every black hole conceals a secret — the quantum remains of the star from which it formed, say a group of scientists, who also predict that these stars can later emerge once the black hole evaporates.

The researchers call these objects "Planck stars" and believe that they could solve a very important question in modern physics: the information paradox, or the question of what happens to information contained in matter that falls into a black hole.

The idea could also finally reconcile quantum mechanics and Albert Einstein’s general theory of relativity that describes gravity, thus showing how a theory of quantum gravity might solve longstanding puzzles in the world of physics. [The Strangest Black Holes in the Universe]

Warping space and time

Black holes are regions of space so incredibly dense that nothing, not even light, can escape from them. Most are thought to form at the end of a big star’s life, when its internal pressure is insufficient to resist its own gravity and the star collapses under its own weight.

Most scientists believe that, since there is nothing to stop this collapse, eventually a singularity will form — a region where infinite densities are reached and Einstein’s general relativity ceases to be predictive.

But this "singularity theory" has flaws. Since the laws of physics no longer apply in a region of infinite density, no one knows what could possibly happen inside a black hole.

Stephen Hawking suggested in the early 1970s that black holes can slowly evaporate and disappear. But in this case, what happens to the information that describes an object that falls into a black hole? According to general relativity, information cannot simply disappear; inside a black hole, however, information apparently does. This "information paradox" has puzzled researchers for decades.

Carlo Rovelli at the University of Marseille in France and Francesca Vidotto at Radboud University in the Netherlands have attempted to answer this question by exploring the idea that the universe, which is assumed to have started with the Big Bang, actually emerged — because of quantum gravitational effects — from a "big bounce," following an earlier contracting phase.

"The quantum gravitational effects produce an effective repulsive force, so that matter wouldn’t have collapsed into a singularity, but it would have just reached a maximal compact state," Vidotto said.

This way, the universe would "bounce" when the energy density of matter reached the Planck scale, the smallest possible size in physics, causing the universe to expand again, and then possibly collapse again, and so on, back and forth. [Alternatives to the Big Bang Theory (Infographic)]

A similar idea has now been proposed for the fate of the collapsing matter of a dying star.Researchers say that quantum effects — similar to those that prevent an electron falling into the nucleus of an atom — would stop the collapse of a star before it could shrink to a single point, or singularity. The star would then become a super-compact object, bounce back during the evaporation process of the black hole and finally explode. Eventually, everything that would have fallen into the black hole would be released.

Black holes are so bizarre, they sound unreal. Yet astronomers have found good evidence they exist. Test your knowledge of these wacky wonders.
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Black Hole Quiz: How Well Do You Know Nature's Weir...
Black holes are so bizarre, they sound unreal. Yet astronomers have found good evidence they exist. Test your knowledge of these wacky wonders.
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 Black holes are strange regions where gravity is strong enough to bend light, warp space and distort time. [<a href="">See how black holes work in this infographic</a>.]
Black holes are strange regions where gravity is strong enough to bend light, warp space and distort time. [See how black holes work in this infographic.]
Credit: Karl Tate, contributor

Gamma-ray bursts

The researchers say that, as the black hole evaporates and shrinks, its boundary will at some point meet that of the Planck star as it expands after the bounce. When that happens, there is no black hole horizon any more, and all information trapped inside the black hole can escape.

In this case, the information paradox would be solved; the information would simply be re-emitted into the universe.

"The black hole has a huge remnant — a Planck star — and this allows us to understand the evaporation of black holes, their final stage of life, without paradoxes. Paradoxes are not part of nature; they are the sign of some incomplete knowledge," Vidotto said.

Rovelli agrees: "Information is never too concentrated, and it can escape with the explosion of the star." This release of information, he estimates, would generate radiation with a wavelength of about 10^-14 cm — the wavelength of gamma rays.

"Now we glimpse a tantalizing possibility: If, in the black holes, matter collapses and then bounces, the expansion can be a very dramatic event, a big explosion," Vidotto said.

And possibly, the scientists add, astronomers have already observed Planck stars releasing the information into space, in the form of extremely bright events called gamma-ray bursts.

No 'end of physics'

Finally, if the theory is confirmed, it could be a solid proof that quantum gravity exists, said Aurelien Barrau of the Joseph Fourier University in Grenoble, France, who was not involved in the study.

"The paper shows that there might be experimental consequences of quantum gravity," he said. "This would be fascinating."

The next step would be to get a more accurate description of the quantum gravitational process that should lead to the "big bounce," possibly with the help of an accurate computer simulation of a realistic collapse, said Stefano Liberati, a physicist at SISSA (International School for Advanced Studies, Trieste, Italy), who did not take part in the research either.

"If the idea [is confirmed] with more detailed calculations, it will be further evidence that what we call singularities in general relativity are just situations where our current theory lack predictability, but are resolved successfully by quantum gravity," he told via email. "At that point, the Big Bang or the center of black holes would not be 'the end of physics' but just another door to be disclosed, leading us to a quantum leap in understanding the nature of our universe."

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