Unique material could unlock new functionality in semiconductors
Researchers synthesized ferroelectric material that can be manipulated using light in previously impossible ways
TROY, N.Y. — If new and promising semiconductor materials are to make it into our phones, computers, and other increasingly capable electronics, researchers must obtain greater control over how those materials function.
In an article published today in Science Advances, Rensselaer Polytechnic Institute researchers detailed how they designed and synthesized a unique material with controllable capabilities that make it very promising for future electronics.
The researchers synthesized the material — an organic-inorganic hybrid crystal made up of carbon, iodine, and lead — and then demonstrated that it was capable of two material properties previously unseen in a single material. It exhibited spontaneous electric polarization that can be reversed when exposed to an electric field, a property known as ferroelectricity. It simultaneously displayed a type of asymmetry known as chirality — a property that makes two distinct objects, like right and left hands, mirror images of one another but not able to be superimposed.
According to Jian Shi, an associate professor of materials science and engineering at Rensselaer, this unique combination of ferroelectricity and chirality is advantageous. When combined with the material’s conductivity, both of these characteristics can enable other electrical, magnetic, or optical properties.
“What we have done here is equip a ferroelectric material with extra functionality, allowing it to be manipulated in previously impossible ways,” Shi said.
The experimental discovery of this material was inspired by theoretical predictions by Ravishankar Sundararaman, an assistant professor of materials science and engineering at Rensselaer. A ferroelectric material with chirality, Sundararaman said, can be manipulated to respond differently to left- and right-handed light so that it produces specific electric and magnetic properties. This type of light-matter interaction is particularly promising for future communication and computing technologies.
This research required an interdisciplinary collaboration among materials scientists, engineers, and physicists at Rensselaer, physicists at Argonne National Laboratory, and chemists from John Hopkins University. First author graduate student Yang Hu, co-advised by Shi and Esther Wertz, an assistant professor of physics, applied physics, and astronomy, mainly worked on the experimental demonstration and Fred Florio, advised by Sundararaman, was responsible for the design and computational work.
About Rensselaer Polytechnic Institute
Founded in 1824, Rensselaer Polytechnic Institute is America’s first technological research university. Rensselaer encompasses five schools, 32 research centers, more than 145 academic programs, and a dynamic community made up of more than 7,900 students and over 100,000 living alumni. Rensselaer faculty and alumni include more than 145 National Academy members, six members of the National Inventors Hall of Fame, six National Medal of Technology winners, five National Medal of Science winners, and a Nobel Prize winner in Physics. With nearly 200 years of experience advancing scientific and technological knowledge, Rensselaer remains focused on addressing global challenges with a spirit of ingenuity and collaboration. To learn more, please visit http://www.
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