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Black holes banish matter to the 'loneliest places in the universe,' scientists claim

The findings could explain why scientists can't find all the matter predicted to exist in the universe

Doug Bolton
Thursday 25 February 2016 15:03 EST
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An image showing the distribution of normal matter in the universe, generated by the Illustris simulation
An image showing the distribution of normal matter in the universe, generated by the Illustris simulation (Markus Haider/Illustris)

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Huge cosmic voids, giant empty regions of the universe which take up space around galaxies, might not be as empty as previously thought, scientists have claimed.

In fact, these voids could contain as much as 20 per cent of the 'normal' matter in the universe, according to a team of astronomers from the University of Innsbruck in Austria.

The scientists believe that this wandering matter was spat out into the void by supermassive black holes in the centre of galaxies.

Using ground and space-based telescopes, scientists have gradually refined their understanding of the composition of the universe. It's currently believed that the universe is made up of around five per cent 'normal' matter, 27 per cent 'dark' matter, and 68 per cent 'dark energy'.

Astronomers have also mapped out galaxies, and indirectly their associated 'dark' matter, showing they are structured in filaments which make up a 'cosmic web'.

The Austrian team investigated this structure in more detail through a simulation named Illustris, and found that around 50 per cent of the total mass in the universe is found in galaxies, compressed into a volume of 0.2 per cent of the visible universe. A further 44 per cent of this mass is found in the filaments, and the final six per cent is found in the voids.

An image showing the distribution of dark matter in a part of the universe, generated by the Illustris simulation
An image showing the distribution of dark matter in a part of the universe, generated by the Illustris simulation (Markus Haider/Illustris)

However, the team were surprised to find that a fairly large proportion of the matter - around 20 per cent - occupies the voids. This appears to be caused by supermassive black holes, which attract matter and convert some of it into energy.

This energy is then delivered to the surrounding gas, and causes large outflows of matter which stretch for hundreds of thousands of light years, beyond their host galaxies and into the voids.

These findings could provide a solution to the 'missing baryon' problem, where astronomers don't see the amount of normal matter predicted by their models. This could be because it's been diffused across the voids by black holes.

Dr Markus Haider, the lead author of a study about the theory which has been published in Monthly Notices of the Royal Astronomical Society, said: "This simulation, one of the most sophisticated ever run, suggests that the black holes at the centre of the galaxy are helping to send matter into the loneliest places in the universe."

He added: "What we want to do now is refine our model, and confirm these initial findings."

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