Researchers detect unexpected quantum effects in natural double-layer graphene

An international research team that included scientists from the University of Göttingen, Ludwig-Maximilians-Universität München, National Institute for Materials Science in Tsukuba, Japan, and University of Texas at Dallas, has detected and interpreted novel quantum effects in high-precision studies of natural double-layer graphene.

This research provides new insights into the interaction of the charge carriers and the different phases, and contributes to the understanding of the processes involved.

When two individual graphene layers are twisted at a very specific angle to each other, the system can become superconducting and also exhibit other quantum effects such as magnetism. However, the production of such twisted graphene double-layers has so far required rather increased technical effort.

This recent study used the naturally occurring form of double-layer graphene, where no complex fabrication is required. In a first step, the sample is isolated from a piece of graphite in the laboratory using a simple adhesive tape. To observe quantum mechanical effects, the team then applied a high electric field perpendicular to the sample: the electronic structure of the system changes and a strong accumulation of charge carriers with similar energy occurs.

At temperatures just above absolute zero of minus 273.15 degrees Celsius, the electrons in the graphene can interact with each other – and a variety of complex quantum phases emerge completely unexpectedly. For example, the interactions cause the spins of the electrons to align, making the material magnetic without any further external influence. By changing the electric field, researchers can continuously change the strength of the interactions of the charge carriers in the double-layer graphene. Under specific conditions, the electrons can be so restricted in their freedom of movement that they form their own electron lattice and can no longer contribute to transporting charge due to their mutual repulsive interaction. The system is then electrically insulating.

"Future research can now focus on investigating further quantum states," said Professor Thomas Weitz and PhD student Anna Seiler, Faculty of Physics at Göttingen University. "In order to access other applications, for example novel computer systems such as quantum computers, researchers would need to find how these results could be achieved at higher temperatures. However, a major advantage of the current system developed in our new research lies in the simplicity of the fabrication of the materials."

Posted: Aug 16,2022 by Roni Peleg