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PUBLIC RELEASE DATE:
8-Jan-2014

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Contact: Tom Abate
tabate@stanford.edu
650-736-2245
Stanford School of Engineering
@stanfordeng

Engineers make world's fastest organic transistor, herald new generation of see-through electronics

Teams from Stanford and the University of Nebraska-Lincoln collaborate to make thin, transparent semiconductors that could become the foundation for cheap, high-performance displays

IMAGE: Transparent transistors on this postage-stamp sized glass have speed characteristics rivaling some forms of silicon transistors. The device, made by collaborators from University of Nebraska-Lincoln and Stanford, used a new...

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Two university research teams have worked together to produce the world's fastest thin-film organic transistors, proving that this experimental technology has the potential to achieve the performance needed for high-resolution television screens and similar electronic devices.

For years engineers the world over have been trying to use inexpensive, carbon-rich molecules and plastics to create organic semiconductors capable of performing electronic operations at something approaching the speed of costlier technologies based on silicon.

In the Jan. 8 edition of Nature Communications, engineers from the University of Nebraska-Lincoln (UNL) and Stanford University show how they created thin-film organic transistors that could operate more than five times faster than previous examples of this experimental technology.

Research teams led by Zhenan Bao, professor of chemical engineering at Stanford, and Jinsong Huang, assistant professor of mechanical and materials engineering at UNL used their new process to make organic thin-film transistors with electronic characteristics comparable to those found in expensive, curved-screen television displays based on a form of silicon technology.

They achieved their speed boost by altering the basic process for making thin film organic transistors.

Typically, researchers drop a special solution, containing carbon-rich molecules and a complementary plastic, onto a spinning platter -- in this case, one made of glass. The spinning action deposits a thin coating of the materials over the platter.

In their Nature Communications paper, the collaborators describe two important changes to this basic process.

First they spun the platter faster. Second they only coated a tiny portion of the spinning surface, equivalent to the size of a postage stamp.

These innovations had the effect of depositing a denser concentration of the organic molecules into a more regular alignment. The result was a great improvement in carrier mobility, which measures how quickly electrical charges travel through the transistor.

The researchers called this improved method "off-center spin coating." The process remains experimental, and the engineers cannot yet precisely control the alignment of organic materials in their transistors, or achieve uniform carrier mobility.

Even at this stage, off-center spin coating produced transistors with a range of speeds far above those of previous organic semiconductors and comparable to the performance of the polysilicon materials used in today's high-end electronics.

Further improvements to this experimental process could lead to the development of inexpensive, high-performance electronics built on transparent substrates such as glass and, eventually, clear and flexible plastics.

Already, the researchers have shown that they can create high-performance organic electronics that are 90 percent transparent to the naked eye.

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Other key members of the research teams included Yongbo Yuan, a postdoctoral associate at UNL's Nebraska Center for Materials and Nanoscience, Gaurav Giri, a graduate student in chemical engineering at Stanford and Alex Ayzner, a postdoctoral researcher at the Stanford Synchrotron Radiation Lightsource.

The work was funded the U.S. Defense Advanced Research Projects Agency (DARPA), the Air Force Office of Scientific Research and the National Science Foundation. Carole Wilbeck of the UNL College of Engineering contributed to this report.

Media Contacts: Tom Abate, Associate Director of Communications at Stanford Engineering, 650-736-2245 or tabate@stanford.edu

Jinsong Huang, assistant professor, mechanical and materials engineering, University of Nebraska-Lincoln 402-472-2640, jhuang2@unl.edu



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