Slightly bending semiconductors made of organic materials can roughly double the speed of electricity flowing through them and could benefit next-generation electronics such as sensors and solar cells, according to Rutgers-led research.
The study is published in the journal Advanced Science.
“If implemented in electrical circuits, such an enhancement – achieved by very slight bending – would mean a major leap toward realizing next-generation, high-performance organic electronics,” said senior author Vitaly Podzorov, a professor in the Department of Physics and Astronomy in the School of Arts and Sciences at Rutgers University-New Brunswick.
Semiconductors include materials that conduct electricity and their conductivity can be tuned by different external stimuli, making them essential for all electronics. Organic semiconductors are made of organic molecules (mainly consisting of carbon and hydrogen atoms) that form light, flexible crystals called van der Waals molecular crystals. These novel materials are quite promising for applications in optoelectronics, which harness light and include flexible and printed electronics, sensors and solar cells. Traditional semiconductors made of silicon or germanium have limitations, including cost and rigidity.
One of the most important characteristics of organic and inorganic semiconductors is how fast electricity can flow through electronic devices. Thanks to progress over the last decade, organic semiconductors can perform roughly 10 times better than traditional amorphous silicon transistors. Tuning semiconductors by bending them is called “strain engineering,” which would open a new avenue of development in the semiconductor industry if implemented successfully. But until now, there were no conclusive experimental results on how bending organic semiconductors, including those in transistors, may affect the speed of electricity flowing in them.
The Rutgers-led study reports the first such measurement, and a 1 percent bend in an organic transistor can roughly double the speed of electrons flowing through it.
The lead author is Hyun Ho Choi, a former post-doctoral researcher in the Podzorov Group who is now at Gyeongsang National University in Korea. Hee Taek Yi, another former post-doctoral researcher, is a coauthor. Scientists at the University of Tokyo; University of Massachusetts Amherst; and Pohang University of Science and Technology in Korea contributed to the study.