The findings of a new study by University of Iowa theoretical physicist Michael Flatté could play a role in the development of future generations of smaller, more energy-efficient computers and electronic devices. Flatté and his team studied friction and drag at the quantum level, the realm of atoms and molecules invisible to the naked eye, and how those forces interact across materials.
Friction and drag are commonplace in nature. You experience these phenomena when riding in an airplane, pairing electrical wiring, or rubbing pieces of sandpaper together.
Flatté proposes that a magnetic current flowing through a magnetic iron sheet will cause a current in a second, nearby magnetic iron sheet, even though the sheets aren’t connected. The movement is created, Flatté and his team say, when electrons whose magnetic spin is disturbed by the current on the first sheet exert a force, through electromagnetic radiation, to create magnetic spin in the second sheet.
This illustration shows how the magnetic fields of individual atoms, reimagined as bar magnets, change position like tiny compasses when heat or a current is applied to a solid material. The repositioning creates a spin wave, shown by the dotted line. These spin waves are being studied for potential use in microelectronics. Illustration courtesy of Michael Flatté laboratory.
The findings may prove beneficial in the emerging field of spintronics, which seeks to channel the energy from spin waves generated by electrons to create smaller, more energy-efficient computers and electronic devices.
“It means there are more ways to manipulate through magnetic currents than we thought, and that’s a good thing,” said Flatté, team leader.
Flatté has been studying how currents in magnetic materials might be used to build electronic circuits at the nanoscale, where dimensions are measured in billionths of a meter, or roughly 1/50,000 the width of a human hair. Scientists knew that an electrical current introduced in a wire will drag a current in another nearby wire. Flatté’s team reasoned that the same effects may hold true for magnetic currents in magnetic layers.
In a magnetic substance, such as iron, each atom acts as a small, individual magnet. These atomic magnets tend to point in the same direction, like an array of tiny compasses fixated on a common magnetic point. But the slightest disturbance to the direction of just one of these atomic magnets throws the entire group into disarray: The collective magnetic strength in the group decreases. The smallest individual disturbance is called a magnon.
Flatté and his team report that a steady magnon current introduced into one iron magnetic layer will produce a magnon current in a second layer—in the same plane of the layer but at an angle to the introduced current. They propose that the electron spins disturbed in the layer where the current was introduced engage in a sort of “cross talk” with spins in the other layer, exerting a force that drags the spins along for the ride.
“What’s exciting is you get this response (in the layer with no introduced current), even though there’s no physical connection between the layers,” said Flatté, professor in the physics department and director of the Optical Science and Technology Center at the UI. “This is a physical reaction through electromagnetic radiation.”
How electrons in one layer communicate and dictate action to electrons in a separate layer is somewhat bizarre.
Take electricity: When an electrical current flows in one wire, a mutual friction drags current in a nearby wire. At the quantum level, the physical dynamics appear to be different. Imagine that each electron in a solid has an internal bar magnet, a tiny compass of sorts. In a magnetic material, those internal bar magnets are aligned. When heat or a current is applied to the solid, the electrons’ compasses get repositioned, creating a magnetic spin wave that ripples through the solid. In the theoretical case studied by Flatté, the disturbance to the solid excites magnons in one layer that then exert influence on the other layer, creating a spin wave in the other layer, even though it is physically separate.
“It turns out there is the same effect with spin waves,” Flatté said.
Contributing authors include Tianyu Liu with the physics and astronomy department at the UI and Giovanni Vignale at the University of Missouri, Columbia.
The US National Science Foundation funded the research through grants to the Center for Emergent Materials.