This morning, the Internet erupted with rumors that physicists have finally observed gravitational waves; ripples in the fabric of spacetime predicted by Albert Einstein a century ago. While it isn’t the first time we’ve heard excited whispers about the elusive phenomena, the gossip feels more promising in light of the recently upgraded detector at the Laser Interferometer Gravitational Wave Observatory (LIGO) that’s behind all the hubbub.
Discovering gravitational waves would be a huge deal for physics, cosmology, and our understanding of the universe at large. But if you’re not a scientist studying one of the aforementioned fields, it’s possible you’ve never heard of these mysterious ripples. What the heck are gravitational waves, and why have physicists been struggling to find them for a century? Moreover, why should we care?
Simply put, gravitational waves are vibrations in the fabric of the universe—light-speed ripples in spacetime itself, caused by such epically violent events as exploding stars and black hole mergers. Thanks to inconceivably large, violent, and distant celestial happenings, the atoms that make up everything from the stars in the sky to the human beings on Earth are shaking a tiny bit, all the time.
And by tiny I really mean tiny. For all the energy that goes into producing gravitational waves, spacetime ripples themselves are incredibly faint. Physicists estimate that by the time gravitational waves reach Earth, they’re on the order of a billionth the diameter of an atom. You need ridiculously precise instruments operating in completely noise-free environments to measure them, and until very recently, our detectors simply haven’t been up to snuff.
Numerical simulation of two merging black holes performed by the Albert Einstein Institute in Germany. Image Credit: Werner Benger / Wikimedia
But the gravitational wave detection game’s been changing of late, with a recent spate of improvements to our leading ground-based observatory, LIGO, and with the launch of the very first space-based gravitational wave detector, LISA Pathfinder
In principle, detecting gravitational waves is quite simple; in practice, it’s maddeningly difficult. What physicists are trying to do is measure small fluctuations in the distance between two objects separated by a known amount. But because the atomic jitters we’re hoping to detect are so damn tiny, we need experiments that can separate objects by huge distances. Even then, we need to measure changes in distance very, very precisely.
That’s the principle behind our current state-of-the-art gravitational wave detectors. In the case of LIGO, which first went online in the early 2000s, two mirrors are hung very far apart (in Richland, Washington and Baton Rouge, Louisiana), forming a primary arm, while another two mirrors are set up perpendicular to that. A beam of laser light is passed through a beam splitter and allowed to bounce back and forth between both arms’ mirrors, many times, before returning to its source.
“If the two arms have identical lengths, then interference between the light beams returning to the beam splitter will direct all of the light back toward the laser,” a Caltech informational website on LIGO explains. “But if there is any difference between the lengths of the two arms, some light will travel to where it can be recorded by a photodetector.”
Simple schematic of the LIGO Detector. Via LIGO.
If that happens, an electrical signal is produced— and it’s up to scientists to determine whether they just witnessed a bona fide gravitational wave. Trouble is, our planet is a noisy place, and a lot of other types of motion, from tremors in the Earth to cars and trains, can muck up the signal. The background noise of our planet, coupled with limitations imposed by the distance of the detectors, has put some serious constraints on our ability to sniff out gravitational waves from the ground. The first LIGO observational campaign, which ended in 2010, turned up no firm evidence, although we were almost fooled by a fake signal deliberately planted by the LIGO Internal Affairs commission to keep scientists on their toes.
But following the 2010 campaign, LIGO underwent a series of upgrades over a five year period. When Advanced LIGO finally came online this past September, its shiny new detectors were three times more sensitive than the initial LIGO experiment. That means Advanced LIGO can now “listen” across a much vaster swath of space—up to 225 million light years away, compared with the 65 million light years distance achieved during the last gravitational wave hunt. And eventually scientists hope to boost Advanced LIGO’s sensitivity to ten times that of the initial LIGO experiment.
The hunt for gravitational waves is also headed to space
Computer model of the LISA pathfinder experimental chambers (gold boxes) and laser interferometer system (center). Via ESA.
There are a few reasons outer space is a compelling place to search for gravitational waves. For one, it’s a much quieter environment than Earth—the only real sources of background noise we have to contend with are solar wind and cosmic radiation, which can be avoided with careful shielding. (In the diagram of the LISA Pathfinder experimental chamber shown above, two test masses are housed in separate electrode boxes, where they’re protected from all external forces. As with LIGO, the distance between them is precisely measured using laser interferometers.)
But the real reason scientists are bringing the hunt for gravitational waves to space has to do with distance. Freed from the spatial constraints of a small rocky planet, we can position objects much further apart, and in doing so cast a much wider net for gravitational waves. While the LISA Pathfinder experiment will attempt to measure the relative position of two masses separated by a mere 15 inches, a future space-based gravitational wave observatory based on LISA’s technology might do the exact same thing over hundreds of thousands of miles.
Why is observing gravitational waves such a big deal? Apart from the fact that it would affirm a big piece of Einstein’s theory of general relativity, gravitational waves can be used to probe some of the most mysterious phenomena in the cosmos. As LISA Pathfinder scientist Bill Weber told Gizmodo
Black holes, neutron stars, and other objects that don’t emit light are very difficult to study directly from our vantage point. But gravitational waves, which pass through such objects like a knife through butter, offer us a window. In probing the dark universe with gravitational waves, we might uncover new celestial wonders we never dreamed of.
LISA Pathfinder, ready to launch in December 2015. Via ESA.
What’s more, as fingerprints of the most energetic events in the universe, gravitational waves can help us understand how the force of gravity operates under extreme conditions; that is, near the strong field limit. There’s a lot we simply don’t know about how gravity works when very massive objects are dancing around one another at speeds approaching that of light.
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Top Image: LISA Pathfinder’s electrode housing chambers, where the first space-based tests for gravitational waves will take place, via CGS SpA.