<p>For the first time, astronomers have discovered a giant string of invisible dark matter across the universe between a pair of galaxy clusters.<br /><br /></p>.<p>The universe is thought to be filled with such strings of dark matter, a mysterious substance that cannot be seen, only sensed through its gravitational pull.<br /><br />Scientists have made many attempts earlier to find dark matter filaments, which are predicted by theories that suggest galaxy clusters form at the intersections of filaments. Dark matter is thought to make up 98 per cent of all matter in the universe.<br /><br />Now, scientists find a giant filament that forms a bridge between two huge clusters called Abell 222 and Abell 223, which lie 2.7 billion light-years away.<br /><br />“This is the first time (a dark matter filament) has been convincingly detected from its gravitational lensing effect,” said Jorg Dietrich,an astronomer at the University Observatory Munich in Germany.<br /><br />“It’s a resounding confirmation of the standard theory of structure formation of the universe. And it’s a confirmation people didn’t think was possible at this point,” Dietrich told SPACE.com.<br /><br />Many astronomers thought detecting filaments would have to wait until telescopes became significantly more advanced, but Dietrich and his colleagues benefited from the rare spatial geometry of this cluster, which allowed them to detect signs of what’s called weak gravitational lensing.<br /><br />According to Albert Einstein’s general theory of relativity, massive objects warp space and time around them, causing anything travelling through it, including light, to proceed along a curved path.<br /><br />When light from a background object, such as a galaxy, passes nearby a massive cluster on its way to Earth, its image will appear bent because of the crooked path its light travelled.<br /><br />“The standard wisdom is that the gravitational lensing of filaments is too weak to be detected with current telescopes,” Dietrich said. “Only when we realised this system has such a peculiar geometry did we realise we have a chance.” <br /></p>
<p>For the first time, astronomers have discovered a giant string of invisible dark matter across the universe between a pair of galaxy clusters.<br /><br /></p>.<p>The universe is thought to be filled with such strings of dark matter, a mysterious substance that cannot be seen, only sensed through its gravitational pull.<br /><br />Scientists have made many attempts earlier to find dark matter filaments, which are predicted by theories that suggest galaxy clusters form at the intersections of filaments. Dark matter is thought to make up 98 per cent of all matter in the universe.<br /><br />Now, scientists find a giant filament that forms a bridge between two huge clusters called Abell 222 and Abell 223, which lie 2.7 billion light-years away.<br /><br />“This is the first time (a dark matter filament) has been convincingly detected from its gravitational lensing effect,” said Jorg Dietrich,an astronomer at the University Observatory Munich in Germany.<br /><br />“It’s a resounding confirmation of the standard theory of structure formation of the universe. And it’s a confirmation people didn’t think was possible at this point,” Dietrich told SPACE.com.<br /><br />Many astronomers thought detecting filaments would have to wait until telescopes became significantly more advanced, but Dietrich and his colleagues benefited from the rare spatial geometry of this cluster, which allowed them to detect signs of what’s called weak gravitational lensing.<br /><br />According to Albert Einstein’s general theory of relativity, massive objects warp space and time around them, causing anything travelling through it, including light, to proceed along a curved path.<br /><br />When light from a background object, such as a galaxy, passes nearby a massive cluster on its way to Earth, its image will appear bent because of the crooked path its light travelled.<br /><br />“The standard wisdom is that the gravitational lensing of filaments is too weak to be detected with current telescopes,” Dietrich said. “Only when we realised this system has such a peculiar geometry did we realise we have a chance.” <br /></p>