Physicists discover novel quantum effect in bilayer graphene
Date:
November 4, 2021
Source:
University of Texas at Dallas
Summary:
Theorists have observed a rare phenomenon called the quantum
anomalous Hall effect in a very simple material. Previous
experiments have detected it only in complex or delicate materials.
FULL STORY ========================================================================== Theorists at The University of Texas at Dallas, along with colleagues
in Germany, have for the first time observed a rare phenomenon called
the quantum anomalous Hall effect in a very simple material. Previous experiments have detected it only in complex or delicate materials.
==========================================================================
Dr. Fan Zhang, associate professor of physics in the School of Natural
Sciences and Mathematics, is an author of a study published on Oct. 6
in the journal Nature that demonstrates the exotic behavior in bilayer graphene, which is a naturally occurring, two-atom thin layer of carbon
atoms arranged in two honeycomb lattices stacked together.
The quantum Hall effect is a macroscopic phenomenon in which the
transverse resistance in a material changes by quantized values in
a stepwise fashion. It occurs in two-dimensional electron systems at
low temperatures and under strong magnetic fields. In the absence of an external magnetic field, however, a 2D system may spontaneously generate
its own magnetic field, for example, through an orbital ferromagnetism
that is produced by interactions among electrons.
This behavior is called the quantum anomalous Hall effect.
"When the rare quantum anomalous Hall effect was investigated previously,
the materials studied were complex," Zhang said. "By contrast, our
material is comparably simple, since it just consists of two layers
of graphene and occurs naturally." Dr. Thomas Weitz, an author
of the study and a professor at the University of Go"ttingen, said: "Additionally, we found quite counterintuitively that even though carbon
is not supposed to be magnetic or ferroelectric, we observed experimental signatures consistent with both." In research published in 2011, Zhang,
a theoretical physicist, predicted that bilayer graphene would have
five competing ground states, the most stable states of the material
that occur at a temperature near absolute zero (minus 273.15 degrees
Celsius or minus 459.67 degrees Fahrenheit). Such states are driven
by the mutual interaction of electrons whose behavior is governed by
quantum mechanics and quantum statistics.
==========================================================================
"We predicted that there would be five families of states in bilayer
graphene that compete with each other to be the ground state. Four have
been observed in the past. This is the last one and the most challenging
to observe," Zhang said.
In experiments described in the Nature article, the researchers found
eight different ground states in this fifth family that exhibit the
quantum anomalous Hall effect, ferromagnetism and ferroelectricity simultaneously.
"We also showed that we could choose among this octet of ground states
by applying small external electric and magnetic fields as well as
controlling the sign of charge carriers," Weitz said.
The ability to control the electronic properties of bilayer graphene
to such a high degree might make it a potential candidate for future low-dissipation quantum information applications, although Zhang and
Weitz said they are primarily interested in revealing the "beauty of fundamental physics." "We predicted, observed, elucidated and controlled
a quantum anomalous Hall octet, where three striking quantum phenomena -- ferromagnetism, ferroelectricity and zero-field quantum Hall effect --
can coexist and even cooperate in bilayer graphene," Zhang said. "Now
we know we can unify ferromagnetism, ferroelectricity and the quantum
anomalous Hall effect in this simple material, which is amazing and unprecedented." Other authors of the Nature article include UT Dallas
physics doctoral student Tianyi Xu and researchers from the University
of Go"ttingen and the Ludwig Maximilian University of Munich.
Zhang's research is funded by the U.S. Army Combat Capabilities
Development Command's Army Research Laboratory and the National Science Foundation.
========================================================================== Story Source: Materials provided
by University_of_Texas_at_Dallas. Original written by Amanda
Siegfried. Note: Content may be edited for style and length.
========================================================================== Journal Reference:
1. Fabian R. Geisenhof, Felix Winterer, Anna M. Seiler, Jakob Lenz,
Tianyi
Xu, Fan Zhang, R. Thomas Weitz. Quantum anomalous Hall octet driven
by orbital magnetism in bilayer graphene. Nature, 2021; 598 (7879):
53 DOI: 10.1038/s41586-021-03849-w ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2021/11/211104162633.htm
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