Researchers at have developed an environmentally safer type of plastic that can be used for wearable electronics, sensors and other electrical applications.
The material, a so-called ferroelectric polymer, is made without fluorine, considered a 鈥渇orever鈥 chemical that hurts the environment because compounds made with it don鈥檛 break down quickly or at all.
Although the researchers are still working to improve the material鈥檚 electric and elastic properties, the potential is vast for its flexibility of electronic uses and eco-friendly structure.
鈥淗ow this material generates its electric properties is also fundamentally new,鈥 said lead researcher Lei Zhu, a professor of macromolecular science and engineering at the Case School of Engineering. 鈥淯nlike current ferroelectric materials, it doesn鈥檛 have to crystallize to lock in the polarity that gives it electrical properties.鈥
The research explaining the discovery was recently published in the journal . The new material is patent pending.
Electronic polymers
Polymers are large molecules comprised of long chains of smaller molecular units that can be man-made鈥攕uch as plastics鈥攐r natural鈥攍ike in a person鈥檚 hair or DNA. By changing a polymer鈥檚 molecular structure and length, it can vary its strength, flexibility, heat-resistance and ability to be recycled.
Ferroelectricity refers to certain materials with what is known as 鈥渟pontaneous polarization鈥 that can be reversed by applying an electric field鈥攍ike an on-off switch. Ferroelectric materials allow for the development of smaller, more efficient electronic devices, reducing our reliance on traditional energy sources.
Flexible on-off switches
The new material Zhu and his research team have created is both flexible and has what is known as tunable electronic properties, which means they can be switched on and off.
They have wide applications in infrared detectors and sensors in wearable electronics, for which the materials need to be soft, pliable and elastic to be compatible with the human body. Conventional ceramic ferroelectric materials are rigid and brittle.
Polymers have the advantage of being flexible and lightweight, but the dominant ferroelectric polymer, poly(vinylidene fluoride), or PVDF, doesn鈥檛 naturally degrade in the environment, making it a 鈥渇orever chemical.鈥 The new material is made without fluorine.
Ferroelectric polymers also have applications in sensors for ultrasound diagnostic tools because they are acoustically compatible with biological tissues. They are also potentially useful in augmented and virtual reality (AR and VR) goggles.
The research was initially supported with a five-year grant from the U.S. Department of Energy in 2017, and subsequently by two grants from the U.S. National Science Foundation, from 2021-25 and renewed to 2028.
鈥淲e鈥檙e still in the development stage of synthesizing small quantities and investigating the properties,鈥 he added. 鈥淏ut we鈥檙e excited about the potential to replace environmentally harmful plastics in sensors and detectors.鈥
The research team includes: from 杏吧视频, , the Perkins Professor of Physics Emeritus, Elshad Allahyarov, visiting professor of physics, Jiahao Huang, research associate in macromolecular science and engineering; and researchers from Penn State University, Vanderbilt University, Brookhaven National Laboratory, Tennessee State University and the University of Tennessee at Knoxville.
