A device made of bilayer graphene, an atomically thin hexagonal arrangement of carbon atoms, provides experimental proof of the ability to control the momentum of electrons.
It also offers a path to electronics that could require less energy and give off less heat than standard silicon-based transistors.
“Current silicon-based transistor devices rely on the charge of electrons to turn the device on or off, but many labs are looking at new ways to manipulate electrons based on other variables, called degrees of freedom,” says Jun Zhu, associate professor of physics at Penn State, who directed the research.
“Charge is one degree of freedom. Electron spin is another, and the ability to build transistors based on spin, called spintronics, is still in the development stage. A third electronic degree of freedom is the valley state of electrons, which is based on their energy in relation to their momentum.”
This new field of physics is called valleytronics.
Think of electrons as cars and the valley states as blue and red colors, Zhu suggests, just as a way to differentiate them. Inside a sheet of bilayer graphene, electrons will normally occupy both red and blue valley states and travel in all directions. The device her PhD student, Jing Li, has been working on can make the red cars go in one direction and the blue cars in the opposite direction.
“The system that Jing created puts a pair of gates above and below a bilayer graphene sheet. Then he adds an electric field perpendicular to the plane,” Zhu says.
“By applying a positive voltage on one side and a negative voltage on the other, a bandgap opens in bilayer graphene, which it doesn’t normally have,” Li explains. “In the middle, between the two sides, we leave a physical gap of about 70 nanometers.”
Inside this gap live one-dimensional metallic states, or wires, that are color-coded freeways for electrons. The red cars travel in one direction and the blue cars travel in the opposite direction. In theory, colored electrons could travel unhindered along the wires for a long distance with very little resistance. Smaller resistance means lower power consumption in electronic devices and the generation of less heat. Both power consumption and thermal management are challenges in current miniaturized devices.
“Our experiments show that the metallic wires can be created,” Li says. “Although we are still a long way from applications.”
Zhu adds, “It’s quite remarkable that such states can be created in the interior of an insulating bilayer graphene sheet, using just a few gates. They are not yet resistance-free, and we are doing more experiments to understand where resistance might come from. We are also trying to build valves that control the electron flow based on the color of the electrons. That’s a new concept of electronics called valleytronics.”
Li worked closely with the technical staff of Penn State’s nanofabrication facility to turn the theoretical framework into a working device.
“The alignment of the top and bottom gates was crucial and not a trivial challenge,” says Chad Eichfeld, a nanolithography engineer.
Their paper appears online in the journal Nature Nanotechnology. Additional authors are from the University of Science and Technology of China, who performed numerical studies to model the behavior of the wires. The high-quality hexagonal Boron Nitride crystals used in the experiment came from Kenji Watanabe and Takashi Taniguchi of National Institute for Material Science in Japan.
The US Office of Naval Research, the National Science Foundation, and funding agencies in China and Japan funded this project. Kenton McFaul, a visiting student from Grove City College, received a grant from the NSF NNIN. Jun Zhu is a member of the Center for 2-Dimensional and Layered Materials in Penn State’s Materials Research Institute.
Source: Penn State