University of Arkansas to study fiber-optic applications for black phosphorous

The NSF awarded $466,954 to University of Arkansas physicists to study black phosphorous.

Hugh Churchill, assistant professor of physics, directs the Quantum Device Laboratory at the University of Arkansas and will study black phosphorus with the help of a NSF award. (Image credit: Russell Cothren/University of Arkansas)
Hugh Churchill, assistant professor of physics, directs the Quantum Device Laboratory at the University of Arkansas and will study black phosphorus with the help of a NSF award. (Image credit: Russell Cothren/University of Arkansas)

IMAGE: Hugh Churchill, assistant professor of physics, directs the Quantum Device Laboratory at the University of Arkansas and will study black phosphorus with the help of a NSF award. (Image credit: Russell Cothren/University of Arkansas)

The National Science Foundation awarded $466,954 to University of Arkansas (Fayetteville, AR) physicists to study the ultrathin material black phosphorous for its potential use in fiber-optic communications. Black phosphorous, which can be thinned down to a single layer of atoms, is an ultrathin semiconductor that has the potential to power optoelectronic devices that use both light and electricity. Some current optoelectronic devices are solar cells and light-emitting diodes, better known as LEDs.

RELATED ARTICLE: Black phosphorus could speed optical communication

"Black phosphorous exhibits strong potential for applications from thin-film electronics to infrared optoelectronics," said Hugh Churchill, an assistant professor of physics and the principal investigator on the project.

The research will shed light on the long-term potential for a new kind of optoelectronic device that would feature an optical switch--the kind needed for fiber-optic communication--in which electricity could control light. Such a switch may be smaller, faster and more energy-efficient than current technologies.

Churchill and Salvador Barraza-Lopez, an assistant professor of physics serving as co-principal investigator on the project, will model and observe the behavior of excitons in black phosphorus. When a semiconductor absorbs light, an electron moves up in energy and leaves behind a hole. This electron and hole can bind together, forming an exciton.

In traditional semiconducting materials such as silicon, excitons are formed at extremely low temperatures, just a few degrees above absolute zero, or they disappear almost instantly. They form at much higher temperatures in black phosphorous, Churchill said.

"These excitons are extraordinarily stable even at room temperature," he said. "Their formation and stability in black phosphorous opens the door for not only observing their behavior at higher temperatures, but the possibility of manipulating them before they disappear."

SOURCE: University of Arkansas; http://news.uark.edu/articles/34787/nsf-awards-467-000-to-u-of-a-physicists-for-black-phosphorus-study

More in Research