“While conducting experiments on a layered metal, EPFL researchers witnessed something very surprising. The unexpected electron behavior they discovered could open up possibilities in the field of quantum computing.
In the world of materials science, sometimes main discoveries can be found in unexpected places. While working on the resistivity of a type of delafossite – PdCoO2 – researchers at EPFL’s Laboratory of Quantum Materials discovered that the electrons in their sample did not behave entirely as expected. When a magnetic field was applied, the electrons retained signatures of their wave-like nature, which could be observed even under relatively high temperature conditions and appeared in relatively large sizes. These surprising results, obtained in collaboration with several research institutions*, could prove useful, for example in the quest for quantum computing. The research will be published today in the prestigious journal Science.
To grasp the significance of this discovery, we need to imagine ourselves on the tiny scale of atoms. At that scale, we see that metals – even though we normally think of them as quite dense – actually consist of a great many empty spaces around the atoms. When electrons move in these interstitial spaces, they have a twofold nature, behaving both as particles and as waves. Usually their movements in a metal wire are captured well by their particle-like aspects, since their wave-like nature is far too faint and masked by various other interactions. Only under highly specific laboratory conditions, particularly at very low temperatures, experiments by Richard Webb and coworkers had famously uncovered the wave character of electrons in metals.
The sample studied was PdCoO2, whose electronic structure is nearly two-dimensional and extremely pure, and which is used as a catalyst in chemistry. The researchers were surprised to observe a new type of oscillations that exhibited significant coherence lengths when the sample was subject to a magnetic field. This coherence is important when trying to preserve quantum states and the conditions under which it occurred should not have been possible under the basic principles of physics. In this case, they were noted at temperatures up to 60 Kelvin and at length scales of up to 12 microns.
“It is gigantic!”
“This is truly surprising,” says Philip Moll, who heads EPFL’s Laboratory of Quantum Materials. “It’s the very first time this quantum effect has been observed in such a large piece of metal. 12 micrometers may seem small, but for the dimensions of an atom, it is gigantic. This is the length scale of biological life, such as algae and bacteria.”
The next step will be to try and better understand how this phenomenon is possible at this scale. But researchers are already imagining a wealth of possibilities, particularly in the field of quantum computing. Stay tuned!
*In collaboration with:
- Max Planck Institute for Chemical Physics of Solids, Germany
- School of Physics and Astronomy, University of St. Andrews, UK
- Max Planck Institute for the Physics of Complex Systems, Germany
- Weizmann Institute of Science, Department of Condensed Matter Physics, Israel
- Laboratoire des Solides Irradiés, Institut Polytechnique de Paris, France”