- It was the first Bose-Einstein condensate made in space.
- Creating the condensate in low gravity allows it to hold longer.
- Scientists hope Bose-Einstein condensate will allow finer detection of subtle quantum phenomena.
For six minutes, 150 miles above Kiruna, Sweden on January 23, 2017 floated the coldest known spot in the universe. As far as we know, the coldest anything in nature can be is absolute zero on the Kelvin scale, which is –459.67°F and –273.15°C. This postage-stamp-sized atom chip packed tight with thousands of rubidium-87 atoms was just a few billionths of a degree warmer than that. The atom chip was up there in low orbit to help a team of scientist study up-close some of the oddest, least-understood stuff there is: Bose-Einstein condensate (BEC). The team of German scientists was led by Dennis Becker of QUEST-Leibniz Research School, Leibniz University Hannover, Hanover, Germany.
Bose-Einstein condensate is the fifth-known form of matter, after solids, liquids, gases, and plasma. When atoms in zero gravity reach a temperature close to absolute zero, they cede their individuality and act as one “super-atom.” A that point, they’re tens of thousands of atoms all vibrating in sync, creating something like a blob in which the tiniest of disturbances can be detected. Scientists hope that BEC can one day be harnessed for gravitational-wave detection.
(Max Planck Institute of Quantum Optics)
The BEC on Earth
In 2010, scientists at the Max Planck Institute of Quantum Optics packed a cylindrical capsule about the size and width of a door with a few million rubidium atoms trapped on an atom chip, lasers, the required energy supply, solenoids, and a camera. They dropped the capsule 146 meters from the top of a tower. It fell for about four seconds, and during the zero gravity of free-fall, they remotely generated a BEC on the atom chip in less than a second. (In the lab, it takes up to a minute.) Once the BEC formed, they released the trap and the camera allowed them to see its spread as it fell. They were able to observe the BEC for a few seconds before it hit bottom.
(Becker, et al)
The mid-winter 2017 space BEC
The January 23rd experiment was the first time anyone’s created the Bose-Einstein condensate in space. The low gravity allowed them to extend the viewing time too the BEC to six minutes, a massive improvement, allowing researcher to race through 110 remote-controlled experiments. The team’s apparatus was launched into space under the auspices of the MAIUS 1, or Matter-Wave Interferometry in Microgravity.
Image: Becker, et al.
The atomic chip
A magneto-optical trap holding the rubidium atoms formed by laser beams (C) is loaded on an atom chip via a cold-atom beam (A). The BEC is created in, transported by, and released from the magnetic trap of the atom chip. Two additional light beams (BD) induce Bragg diffraction scattering the BEC, and a charge-coupled device (CCD) camera records the BEC using laser light (D).
(Becker, et al)
Hurry up and experiment
In one significant experiment, researchers split the BEC with a laser and then were able to watch it rejoin. This could be an important technique because upon parting, the two halves were identical on a quantum level, and any differences observed after rejoicing would indicate some sort of interference, such as a gravitational wave.
NASA has its own Cloud Atom Lab, an ice-chest-sized environment deployed on the ISS for low-gravity BEC research. While Becker’s team made the first space BEC, the NASA team has reportedly been extending the time a BEC can be maintained.