NASA will create coldest place in universe to study quantum physics
NASA’S COLDEST PLACE ON EARTH
The coldest place in universe, Beyond the bounds of our planet, the record for the coldest temperature is currently held by the Boomerang Nebula, a swiftly moving chill cloud of dust and gas that stays at a cool one degree Kelvin, or –458°F. Down here on the ground, physicists managed to surpass that last year, chilling an object to a stunning 0.00036 degrees Kelvin or -459.669352°F.
Researchers will create Bose-Einstein condensates in CAL by slowing down atoms until they are almost motionless, at which point the atoms start acting like a wave instead of particles—behavior that’s more quantum physics than conventional physics. That behavior is why Bose-Einstein condensates are of such great interest to researchers who study quantum mechanics. On Earth though, researchers have only gotten Bose-Einstein condensates to persist for fractions of a second before the gas is pulled down by gravity and disrupted. In the microgravity of the ISS though, they hope to have up to a leisurely 10 seconds of observation time.
It’s hard to study quantum behavior on Earth. You can amplify the effects of quantum mechanics by zapping groups of specific atoms (Bose-Einstein condensates) with lasers that drop their temperature to near absolute zero, but that only works for fractions of a second before gravity invariably takes over. NASA’s solution? Create the coldest known place in the universe. The agency just launched the Cold Atom Lab, a box that takes advantage of microgravity aboard the International Space Station to keep condensates in that ideal state for much longer.
The box creates a temperature roughly 10 billion times colder than the vacuum of space and then uses a combination of lasers and electromagnetism to slow atoms until they’re virtually stationary. At that point, quantum mechanics override conventional physics and make the atoms behave more like waves than particles. In the very low gravity environment of the ISS, those atoms should hold their wave-like state for roughly five to 10 seconds — still a brief window, but much easier to study.
The extra analysis time could lead to a greater understanding of quantum physics, which in turn could be applied to quantum computing. It may also help us detect dark energy, the most common substance in the universe. While you may not see results for a long time, the lab’s impact might be felt for a long, long time to come.