Research

Researchers identify breaking point of conducting material

NSF-funded study may accelerate the development of flexible electronics

Conjugated polymers are an important element in the development of flexible electronics such as bendable cellphones.  Credit: iStock/@DevrimbAll Rights Reserved.

UNIVERSITY PARK, Pa. — An improved method to predict the temperature when plastics change from supple to brittle, which could potentially accelerate future development of flexible electronics, was developed by Penn State College of Engineering researchers.

Next-generation flexible electronics, such as bendable displays and medical implants, will rely on semiconductor materials that are mechanically flexible. Accurate predictions of the temperature when embrittlement occurs, known as the glass transition temperature, is crucial to design conducting polymers that remain flexible at room temperature. 

“Previous work to predict the glass transition of polymers relied on complex, multi-parameter models but nevertheless led to poor accuracy,” said Enrique Gomez, professor of chemical engineering and principal investigator. “In addition, accurate experimental measurements of the glass transition of conjugated polymers are challenging.” 

All polymers become brittle when cooled. However, some polymers, such as polystyrene used in Styrofoam cups, become brittle at temperatures higher than room temperature while other polymers, such as polyisoprene used in rubber bands, become brittle at much lower temperatures.  

Renxuan Xie, previously a doctoral student at Penn State and now a postdoctoral researcher at the University of California at Santa Barbara, found a way to measure glass transition temperatures by keeping track of the mechanical properties as embrittlement occurs, laying the foundation for understanding the relationship between the glass transition and structure. Follow-up studies then determined the glass transition for 32 different polymers by measuring mechanical properties as a function of temperature.  

“This advancement, coupled with data for various polymers in our later studies, revealed a simple relationship between the chemical structure and the glass transition,” Gomez said. “Therefore, we can now predict the embrittlement point from the chemical structure.”

According to Gomez, this work, reported in a recent issue of Nature Communications, allows researchers to predict the glass transition temperature from the chemical structure of conducting polymers before they are synthesized for use in electronics. Most currently used conducting polymers are brittle and inflexible, so this advancement could accelerate the development of flexible electronics.  

“Although it sounds simple, we’re the first to use the mechanical properties of conducting polymers to measure the glass transition temperature,” Gomez said. “We combine the data from many different polymers to derive a simple relationship that predicts the glass transition temperature based on the chemical structure in a more accurate way than previously possible.”  

Gomez’s study was funded by a four-year, $1.75 million grant awarded in 2019 by the National Science Foundation to explore the integration of theory, simulations and experiments to accelerate the development of flexible electronics based on organic compounds. The next steps for this research, Gomez said, are more extensive tests and exploration of practical applications. 

“We now want to use our model to design conducting polymers to make ultra-flexible and stretchable electronics,” Gomez said. “We also want to push our model to find the limits and see where the model breaks down.” 

Along with Gomez and Xie, Penn State researchers in the study include Ralph Colby, co-principal investigator and professor of materials science and engineering and chemical engineering; Christian Pester, assistant professor of chemical engineering and materials science and engineering; Albree Weisen, undergraduate student in chemical engineering at the time of the work and now a graduate student at the University of Akron; Youngmin Lee, postdoctoral researcher at the time of the work and now assistant professor of chemical engineering at New Mexico Tech; Melissa Aplan, graduate student in chemical engineering and now senior research specialist with Dow Chemical; Abigail Fenton, graduate student in chemical engineering; and Ashley Masucci, graduate student in chemical engineering.

Fabian Kempe, graduate student in chemical engineering, and Michael Sommer, professor of polymer chemistry at Chemnitz University of Technology, also participated in this work.

 

Last Updated June 1, 2020

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