Fifth state of matter created on the space station (ISS)

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Fifth state of matter created on the space station (ISS)
Fifth state of matter created on the space station (ISS)

A new study describes how the mission became the first to make a fifth state of matter in Earth orbit, and the advantages of studying atoms in space.

This month marks 25 years since scientists first produced a fifth state of matter, which has extraordinary properties totally unlike solids, liquids, gases and plasmas. The achievement garnered a Nobel Prize and changed physics.

A new study in the journal Nature builds on that legacy. In July 2018, NASA’s Cold Atom Lab became the first facility to produce that fifth state of matter, called a Bose-Einstein condensate (BEC), in Earth orbit. A fundamental physics facility on the International Space Station, Cold Atom Lab cools atoms down to ultracold temperatures in order to study their basic physical properties in ways that would not be possible on Earth. Now, the mission team reports on the details of getting this unique lab up and running, as well as their progress toward a long-term goal of using microgravity to illuminate new features of the quantum world.

Whether you know it or not, quantum science touches our lives each day. Quantum mechanics refers to the branch of physics that focuses on the behaviors of atoms and subatomic particles, and it is a foundational part of many components in many modern technologies, including cell phones and computers, that employ the wave nature of electrons in silicon.

Although the first quantum phenomena were observed more than a century ago, scientists are still learning about this realm of our universe.

“Even dating back to when the first Bose-Einstein condensates were made, physicists recognized how working in space could provide big advantages in studying these quantum systems,” said David Aveline, a member of the Cold Atom Lab science team at NASA’s Jet Propulsion Laboratory in Southern California. “There have been some focused demonstrations in this regard, but now with the continuous operation of Cold Atom Lab, we’re showing there’s a lot to gain by doing these prolonged experiments day after day in orbit.”

The colder atoms are, the slower they move and the easier they are to study. Ultracold atom facilities like Cold Atom Lab cool atoms down to within a fraction of a degree above absolute zero, or the temperature at which they would theoretically stop moving entirely.

Chilling atoms is also the only way to produce a Bose-Einstein condensate. Scientists produce BEC’s in a vacuum, so on Earth the atoms are pulled down by gravity and fall quickly to the floor of the chamber, typically limiting observation times to less than a second. With the weightlessness of the space station, BEC’s can float, not unlike the astronauts on board. Inside Cold Atom Lab, that means longer observing times.

Unlike solids, liquids, gases and plasmas, BEC’s don’t form naturally. They serve as a valuable tool for quantum physicists because all the atoms in a BEC have the same quantum identity, so they collectively exhibit properties that are typically displayed only by individual atoms or subatomic particles. Thus, BEC’s make those microscopic characteristics visible at a macroscopic scale.

Previous ultracold atom experiments have used sounding rockets or dropped their specially designed hardware from the top of tall towers to create seconds or minutes of weightlessness the same way a zero gravity airplane does. From its perch on the station, Cold Atom Lab has provided its scientists thousands of hours of microgravity experiment time. This allows them to repeat their experiments multiple times and to exercise more creativity and flexibility in the experiments they conduct.

“With Cold Atom Lab, scientists can see their data in real time and make adjustments to their experiments on short notice,” said Jason Williams, a member of the Cold Atom Lab science team at JPL. “That flexibility means we’re able to learn quickly and address new questions as they arise.”

Ultracold atom facilities in space should also be able to reach colder temperatures than Earth-bound laboratories. One way to do that is to simply make the ultracold atom clouds slowly expand, which causes them to get cooler and is easier to do without gravity pulling atoms to the ground.

Longer observing times and colder temperatures both provide opportunities for deeper insights into the behaviors of atoms and BEC’s. On Earth, the coldest temperatures and longest observing times have been achieved only by experiments with entire rooms full of dedicated hardware or tall towers. The dishwasher-sized Cold Atom Lab hasn’t yet set new records in those categories, but its basic capabilities are cutting edge, bundling the abilities of an extremely large lab into a small package.

“I really think we’ve just begun to scratch the surface of what can be done with ultracold atom experiments in microgravity,” said Ethan Elliott, a member of the Cold Atom Lab science team at JPL. “I’m really excited to see what the fundamental physics community does with this capability in the long term.”

Cold Atom Lab has now run successfully for two years, and astronauts recently helped upgrade the facility with a new tool called an atom interferometer that uses atoms to precisely measure forces, including gravity. The team recently confirmed that the new instrument is working as expected, making it the first atom interferometer to operate in space.

The new study in Nature was led by Aveline, Williams and Elliott. Designed and built at JPL, Cold Atom Lab is sponsored by the Space Life and Physical Sciences Research and Applications (SLPSRA) division of NASA’s Human Exploration and Operations Mission Directorate at the agency’s headquarters in Washington and the International Space Station Program at NASA’s Johnson Space Center in Houston.

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