JILA researchers have made a long-lived, record-cold gas of molecules that follow the wave patterns of quantum mechanics instead of the strictly particle nature of ordinary classical physics. The creation of this gas boosts the odds for advances in fields such as designer chemistry and quantum computing.
As featured on the cover of the Feb. 22 issue of Science, the team produced a gas of potassium-rubidium (KRb) molecules at temperatures as low as 50 nanokelvin (nK). That’s 50 billionths of a Kelvin, or just a smidge above absolute zero, the lowest theoretically possible temperature. The molecules are in the lowest-possible energy states, making up what is known as a degenerate Fermi gas.
In a quantum gas, all of the molecules’ properties are restricted to specific values, or quantized, like rungs on a ladder or notes on a musical scale. Chilling the gas to the lowest temperatures gives researchers maximum control over the molecules.
The two atoms involved are in different classes: Potassium is a fermion (with an odd number of subatomic components called protons and neutrons) and rubidium is a boson (with an even number of subatomic components). The resulting molecules have a Fermi character.
“The basic techniques for making the gas are the same ones we’ve used before, but we have a few new tricks such as significantly improving the cooling of the atoms, creating more of them in the lowest-energy state,” NIST/JILA Fellow Jun Ye said. “This results in a higher conversion efficiency so we get more molecules.”
The JILA team produced 100,000 molecules at 250 nK and as many as 25,000 molecules at 50 nK.
(Source/release by JILA)