Posted on

How to catch the biggest wave in the universe

When it comes to waves, it doesn't get much bigger than the gravitational variety. 

Einstein predicted that huge events — like black holes merging — create gravitational waves. Unlike most waves we experience, these are distortions in space and time. They roll across the entire universe virtually unimpeded.

Einstein first predicted the existence of gravitational waves in 1916, but none were spotted until recently. Given their incredible power, why did it take a century to locate them?

To find out, I went to see where the detection finally occurred. It's just off Interstate 12 in Livingston Parish, La. To get there you head through town, past the "Gold and Guns" pawn shop and up a country road. Turn onto an empty lane and eventually some low buildings emerge from a forest of gangly pine trees.

Ligo Livingston Aerial 03 Da1B08Ce6497F7B5F28Bf1Fad05Ee09Ca880C232 S800 C85

This is the Laser Interferometer Gravitational Wave Observatory. That's kind of a mouthful, so scientists just call it LIGO.

Because gravitational waves warp space, they literally change how long things are. LIGO is basically the world's most complicated tape measure.

We walk up a little hill overlooking the machine. A drab concrete pipe stretches off toward the flat Louisiana horizon. Giaime explains that this is one of the LIGO's two arms.

Bsc1 130606 13 52 43 189Ba31B7E150672179D62D44C7A24B257Ddb55C S800 C85

Lasers and mirrors are used to measure the shifts in space and time caused by the waves

The machine is in the shape of a giant letter L. When a gravitational wave passes by, one arm of the machine gets a little shorter and the other one gets a little longer. The machine measures the difference in length. And that's all there is to it.

At least, in theory.

Nerves set in

The search started more than a decade ago. But for a long time, LIGO didn't see anything.

"Up until last year, we would give tours to little kids, and at the end of the tour, they would say, 'so what have you seen, what have you measured?' " Giaime says. "And the answer was, 'Nothing! Nothing yet.'"

Giaime began to get nervous. "I can personally say I was wondering if there was some sort of misunderstanding about what was out there in the universe," he says.

But he and the rest of the team kept at it. Upgrading the lasers and tweaking the mirrors. Finally, on September 14, 2015 at 5:51 in the morning, a wave passed through this detector and the machine vibrated — like a giant tuning fork listening to space and time.

Moments later, an identical detector in the state of Washington picked it up, too. The signal was real.

It was all that was left of the massive wave created when two black holes collided billions of years ago. The wave is small now, but at the moment of the merger, the power released was greater than all the stars combined.

It truly was the biggest wave in the universe.

ex arrow-right check news twitter facebook