Posted in | Quantum Physics

Cold Physics Experiments Could Provide Much Greater Understanding of Quantum Mechanics

It is said that what goes up must come down. Thank gravity for that. But sometimes gravitational effects affect matter on Earth in ways that physicists would rather do without. So early next year NASA is launching to the International Space Station a novel “Cold Atom Laboratory” that will allow physicists to conduct sustained experiments into the states of matter, under nearly weightless conditions, at ultra-cold temperatures, that would be nearly impossible to conduct on Earth.

“The chance to do experiments that sound like science fiction, on a space ship, is almost a dream come true,” said Cass Sackett, of his NASA project. (Credit: Dan Addison, University Communications)

University of Virginia physicist Cass Sackett is part of the mission.

“We will make use of the near-weightless conditions of orbit to help us suspend atoms, slow them down, and thereby cool down, the motions of atoms,” he said. “These cold physics experiments should provide a much greater understanding of quantum mechanics and gravity, and provide some practical uses as well.”

Quantum mechanics is the fuzzy area of particle physics where atoms apparently lose individuality and group into a “quantum wave,” where each atom somehow is in many places at exactly the same time, essentially defying the practical, everyday laws of Newtonian physics – while functioning perfectly according to the natural state of affairs in the quantum realm. Physicists have puzzled and pondered on these uncertainty properties of atoms for decades.

The Cold Atom Lab project should help bring theory to practice as scientists manipulate nature with lasers and magnets in a mini lab in a location literally out of this world: the space station. And the experiments will not only satisfy the natural curiosities of physicists, but also should lead to applications such as highly precise navigational systems for space travel, including future Mars missions, and ways to better measure gravitational variations on Earth that can improve mapping, resource exploration and more.

“We believe we can cool down atoms to less than a billionth of a degree above absolute zero [about minus-460 degrees Fahrenheit], something that doesn’t occur in nature,” Sackett said. “This will slow down the atoms to the pace of a snail, allowing us to observe activity we’ve never seen on Earth. To do this, we need to work in a near-zero gravity environment and sustain atoms in a weightless state for relatively lengthy periods of time.”

The effect will create new states of matter, as atoms unrestrained by gravity become ultra-cold and behave as they will – in new states and conditions – under the close scrutiny of Earth-bound physicists. Sackett and his peers at other universities will share time on the Cold Atom Lab, conducting their experiments remotely, similar to land-based astronomers using space observatories.


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