MIT researchers and colleagues recently discovered an important — and unexpected — electronic property of graphene, a material discovered only about 17 years ago that continues to surprise scientists with its interesting physics. The work, which involves structures composed of atomically thin layers of materials that are also biocompatible, could usher in new, faster information-processing paradigms. One potential application is in neuromorphic computing, which aims to replicate the neuronal cells in the body responsible for everything from behavior to memories.
The work also introduces new physics that the researchers are excited to explore.
“Graphene-based heterostructures continue to produce fascinating surprises. Our observation of unconventional ferroelectricity in this simple and ultra-thin system challenges many of the prevailing assumptions about ferroelectric systems, and it may pave the way for an entire generation of new ferroelectrics materials,” says Pablo Jarillo-Herrero, the Cecil and Ida Green Professor of Physics at MIT and leader of the work, which involved a collaboration with five other MIT faculty from three departments.
A new property
Graphene is composed of a single layer of carbon atoms arranged in hexagons resembling a honeycomb structure. Since the material’s discovery, scientists have shown that different configurations of graphene layers can give rise to a variety of important properties. Graphene-based structures can be either superconductors, which conduct electricity without resistance, or insulators, which prevent the movement of electricity. They have even been found to display magnetism.
In this work, which was reported in Nature, the MIT researchers and colleagues show that bilayer graphene can also be ferroelectric. This means that positive and negative charges in the material can spontaneously separate into different layers.
In most materials, opposite charges are attracted to each other; they want to combine. Only the application of an electric field will force them to opposite sides, or poles. In a ferroelectric material, no external electric field is necessary to keep the charges apart, giving rise to a spontaneous polarization. However, the application of an external electric field does have an effect: an electric field of opposite direction will cause the charges to switch sides and reverse the polarization.
For all of these reasons, ferroelectric materials are used in a variety of electronic systems, from medical ultrasounds to radio frequency identification cards.
Conventional ferroelectrics, however, are insulators. The MIT-led team’s ferroelectric based on graphene operates through a completely different mechanism — different physics — that allows it to conduct electricity. And that opens up myriad additional applications. “What we’ve found here is a new type of ferroelectric material,” says Zhiren “Isaac” Zheng, an MIT graduate student in physics and first author of the Nature paper.
Qiong Ma PhD ’16, a co-author of the paper and an assistant professor at Boston College, puts the work in perspective. “There are challenges associated with conventional ferroelectrics that people have been working to overcome. For example, the ferroelectric phase becomes unstable as the device continues to be miniaturized. With our material, some of those challenges may be automatically solved.” Ma conducted the current work as a postdoc through MIT’s Materials Research Laboratory (MRL).
In addition to Jarillo-Herrero, Zheng, and Ma, additional authors of the paper are Zhen Bi of Pennsylvania State University; Sergio de la Barrera, a postdoc in the MRL; Ming-Hao Liu of National Cheng Kung University; Nannan Mao, a postdoc in MIT’s Research Laboratory of Electronics; Yang Zhang, a postdoc in the MRL; Natasha Kiper of ETH Zürich; Professor Jing Kong of MIT’s Department of Electrical Engineering and Computer Science; William Tisdale, the ARCO Career Development Professor in MIT’s Department of Chemical Engineering; Professor Ray Ashoori of the MIT Department of Physics; Professor Nuh Gedik of the Department of Physics; Liang Fu, MIT’s Lawrence C. (1944) and Sarah W. Biedenharn Career Development Associate Professor of Physics, and Su-Yang Xu of Harvard University.
The structure the team created is composed of two layers of graphene — a bilayer — sandwiched between atomically thin layers of boron nitride (BN) above and below. Each BN layer is at a slightly different angle from the other. Looking from above, the result is a unique pattern called a moiré superlattice. A moiré pattern, in turn, “can dramatically change the properties of a material,” Zheng says.
Jarillo-Herrero’s group demonstrated an important example of this in 2018. In that work, also reported in Nature, the researchers stacked two layers of graphene. Those layers, however, weren’t exactly on top of each other; rather, one was slightly rotated at a “magic angle” of 1.1 degrees. The resulting structure created a moiré pattern that in turn allowed the graphene to be either a superconductor or an insulator depending on the number of electrons in the system as provided by an electric field. Essentially the team was able to “tune graphene to behave at two electrical extremes.”
“So by creating this moiré structure, graphene is not graphene anymore. It almost magically turns into something very, very different,” Ma says.
In the current work, the researchers created a moiré pattern with sheets of graphene and boron nitride that has resulted in a new form of ferroelectricity. The physics involved in the movement of electrons through the structure is different from that of conventional ferroelectrics.
“The ferroelectricity demonstrated by the MIT group is fascinating,” says Philip Kim, a professor of physics and applied physics at Harvard University, who was not involved in the research. “This work is the first demonstration that reports pure electronic ferroelectricity, which exhibits charge polarization without ionic motion in the underlying lattice. This surprising discovery will surely invite further studies that can reveal more exciting emergent phenomena and provide an opportunity to utilize them for ultrafast memory applications.”
The researchers aim to continue the work by not only demonstrating the new material’s potential for a variety of applications, but also developing a better understanding of its physics. “There are still many mysteries that we don’t fully understand and that are fundamentally very intriguing,” Ma says.
This work was supported by the U.S. Department of Energy, the Gordon and Betty Moore Foundation, the U.S. Air Force Office of Scientific Research, the U.S. National Science Foundation, the Ministry of Education, Culture, Sports, Science and Technology (MEXT) of Japan, and the Taiwan Ministry of Science and Technology.
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