Members of the Jin group found a way to measure for the first time the a type of abstract “surface” in a gas of ultracold atoms that had been predicted in 1926 but not previously observed. Jin and her colleagues are leading researchers in the field of ultracold Fermi gases made up of thousands to millions of fermions.
Fermions, including electrons and some types of atoms such as potassium (40K), cannot occupy exactly the same quantum state. This property leads to a unique distribution of the energy, or speed, of a collection of fermions at low temperature. The distribution has a sharp boundary called a Fermi surface (Figure 1). And, under the right conditions, an ultracold gas of fermions should exhibit a sharp step, or boundary, in the distribution of speeds.
Famous physicists Enrico Fermi and Paul Dirac predicted the existence of this step nearly 100 years ago. For most of a century, physicists were unable to directly see the Fermi surface by looking at the speeds of a bunch of fermions. One difficulty was that fermions interact in virtually all systems except for ultracold gases where interactions can be controlled by adjusting the magnetic field.
However, confining ultracold gas clouds in traps (using light or magnetic fields) does cause variations in the density of the gas in different parts of the cloud. These density variations wash out the sharp Fermi surface when speed distributions are averaged over an entire ultracold gas cloud. So, although physicists were sure that a Fermi surface was present in small sections of the clouds of ultracold fermions, they were unable to “see” it experimentally.
However, seeing it experimentally was exactly what the Jin group wanted to do. So research associate Yoav Sagi, graduate students Tara Drake and Rabin Paudel, former graduate students Jayson Stewart and John Gaebler, and Fellow Jin devised a clever strategy that allowed them to see a sharp Fermi surface for the first time since it was predicted in 1926. The group used two perpendicular laser beams to probe just the atoms near the center of the ultracold Fermi gas. The researchers thought there was a good chance that the density inside the tiny “box” they were targeting would be uniform enough to reveal a Fermi surface in a speed distribution.
The final step of the experiment was to turn off the lasers and measure the speed of the atoms in the box as they expanded out of the trap. These measurements (Figure 2) revealed a clear Fermi surface. Its location and sharpness allowed the researchers to determine both the average density and the temperature of the fermions inside the box!
The Jin group is really excited about this accomplishment. It’s not everyday that experimental physicists are finally able to figure out how to directly observe a 100-year old prediction.