LIGO

A photo of rings from a neutron star's flare.
NASA / WIKIMEDIA COMMONS

Scientists have spent centuries studying how matter works. They’ve boiled it, they’ve frozen it, and they’ve even thrown it into particle colliders and smashed it up. They’ve learned a lot about what matter does in these conditions, but--that’s just what we can do on Earth.

“A neutron star is basically the densest object aside from a black hole. When they collide, the matter itself is deformed in such a way that we can probe densities inaccessible to laboratories on Earth,” Leslie Wade said.

A visualization of Einstien's theory of gravitational waves.
NASA / Wikimedia Commons

In 1916, Einstein made a bold prediction- that gravity actually travels in waves. These “gravitational waves” would be ripples in the fabric of space a bit like ripples on a pond, and would slightly stretch and squash the distances between things as they passed.  

“Einstein himself who came up with the theory didn’t think that this would ever really be detected,” Kenyon College professor Leslie Wade said.

CALTECH/MIT/LIGO LAB

In 1916, Einstein made a bold prediction-- that gravity actually travels in waves. These “gravitational waves” would be ripples in the fabric of space a bit like ripples on a pond, and would slightly stretch and squash the distances between things as they passed.