Graduate student Anh Tuan Ngo and faculty member Sergio Ulloa. Photo credit: Erica McKeehan

(麻豆淫院Org.com) -- For decades, the transistors inside radios, televisions and other everyday items have transmitted data by controlling the movement of the electron鈥檚 charge. Scientists now have discovered that transistors could use less energy, generate less heat and operate at higher speeds if they exploited another property of the electron: its spin.

In 1921, scientists discovered that each electron has spin鈥攁n inherent that makes the electron twirl as it moves around an axis. Since then, researchers around the world and at Ohio University have been developing that embed data inside an electron鈥檚 spin. The emerging field of spin electronics鈥攐r spintronics鈥攃ould revolutionize devices and quantum computers.

Until now, scientists developing spin electronics have controlled spin by attaching an external magnet directly to the devices. But with the demand for smaller transistors on the rise, using a bulky magnet is not an efficient or practical way to manipulate the orientation of an electron鈥檚 spin, said Sergio Ulloa, professor of physics and astronomy at Ohio University.

鈥淭he holy grail in is to address spin with something other than magnets,鈥 said Ulloa. 鈥淎n electrical field is portable and easy to switch on and off.鈥

Ulloa and graduate student Anh Tuan Ngo helped solve this problem by providing theoretical modeling for a recent experiment that was the first to successfully control an electron鈥檚 spin using purely electrical fields. These findings were published in the journal Nature Nanotechnology.

The team collaborated with a research group at the University of Cincinnati, led by Philippe Debray and Marc Cahay. Debray conceived and designed the experiments. The Ohio University researchers鈥 calculations explained the behavior of the in Debray鈥檚 experimental conditions and predicted how strong the electric field鈥檚 control over the spin would be.

Their research also revealed one of the key conditions of the experiment鈥攖hat the tiny connection along which the electrons travel in the device must be asymmetrical.

鈥淚magine that you鈥檙e walking through a forest and there are mountains on either side of you. If on one side the mountains are taller, you will be able to tell which direction you are walking,鈥 Ulloa said. 鈥淭he electron will know there is asymmetry, and its spin will be able to tell which way is up.鈥

Controlling spin electronically has major implications for the future of novel devices such as transistors, but this experiment is only the first step of many, Ulloa said. The next step would be to rework the experiment so that it could be performed at a higher, more practical temperature not requiring the use of liquid helium.

Provided by Ohio University ( : )