By KATHLEEN LAUFENBERG
TALLAHASSEE, Fla. — Simple methods can result in surprising and environmentally friendly high-tech outcomes.
That's part of what MagLab physicist Eden Steven discovered during his innovative experiments with spider silk and carbon nanotubes, the results of which are now published in Nature Communications, a high-quality online journal dedicated to biological, physical- and chemical-science research.
"If we understand basic science and how nature works, all we need to do is find a way to harness it," Steven says. "If we can find a smart way to harness it, then we can use it to create a new, cleaner technology."
Steven — the lead investigator on the paper "Carbon nanotubes on a spider silk scaffold" — collaborated with six other scientists, including Florida State University Physics Department Chair James Brooks and Fulbright scholar and Iraqi physicist Wasan Saleh. Saleh worked with Steven and Brooks at the MagLab in the summer of 2011, one of 10 Iraqi Fulbright scholars, and the only woman in the Iraqi group, to visit FSU that summer.
The scientists' experimental, eco-friendly recipe revolved around three main ingredients. Two are quite familiar — spider silk and water — while the third, carbon nanotubes, is hi-tech. You can think of a nanotube as a one-atom thick sheet of carbon that's been rolled into an infinitesimally tiny tube. A nanotube's diameter is at least 10,000 times smaller than a strand of human hair. Physicists know that when things get that microscopically minute, they act very strange. Researchers worldwide are intrigued by the properties of carbon nanotubes, including their amazing strength and ability to conduct electricity and heat.
Steven wanted to see what would happen when strands of spider's silk were coated with carbon nanotubes. Keeping with his theme of simplicity, he gathered the spider silk himself, hiking around the MagLab and using a stick to gather webs. To adhere the powdery carbon nanotubes to the spider silk, he ultimately discovered that just a drop of water worked best. The dazzling results have drawn the attention of national media. Steven, now unofficially known as the MagLab's Spider-Man, has already been interviewed by Discovery News, New Scientist, Materials 360 and The Hindu.
"It turns out that this high-grade, remarkable material has many functions," Steven says of the silk coated in carbon nanotubes. "It can be used as a humidity sensor, a strain sensor, an actuator (a device that acts as an artificial muscle, for lifting weights etc.) and as an electrical wire."
To determine if his "spider wire" would conduct electricity when severely bent, Steven formed the wire into the acronym FSU. It worked! The actual letters were small enough to fit on a man's wedding band.
Steven was also interested in spider wire because of it's an eco-friendly material. Many of today's electronic devices contain toxic elements and complex, non-biodegradable plastics that end up as pollution in our environment. His spider wire is able to handle changes in humidity without complicated treatments and chemical additives.
"Understanding the compatibility between spider silk and conducting materials is essential to advance the use of spider silk in electronic applications," Steven wrote in the Nature Communications paper. "Spider silk is tough, but becomes soft when exposed to water. … The nanotubes adhere uniformly and bond to the silk fiber surface to produce tough, custom-shaped, flexible and electrically conducting fibers after drying and contraction."
In addition to Saleh, with the University of Baghdad, the other researchers who collaborated on the paper were: Steve F.A. Acquah, with the FSU's Department of Chemistry and Biochemistry; Rufina G. Alamo, with the FAMU-FSU Department of Chemical and Biomedical Engineering; Victor Lebedev, with the Institute of Materials Science of Barcelona; and Vladimir Laukhin, with the Catalan Institution for Research and Advanced Studies (ICREA) in Barcelona.
Fostering such diverse scientific alliances is part of what makes the MagLab a dynamic workplace.
"The Magnet Lab and its sister materials centers at FSU provide an interdisciplinary environment that attracts the expertise of scientists from across the entire university and around the world to come here to do collaborative science," says MagLab physicist Brooks. "In such an environment the scientific imagination can run wild in unexpected directions."
This work was supported by the National Science Foundation, the Department of Energy and the State of Florida. MagLab scientist Yi-Feng Su and Xixi Jia assisted with the transmission electron microscopy study; MagLab postdoctoral associate Jin Gyu Park assisted in the tensile measurement and Raman spectroscopy study; and spectroscopy facilities were provided by FSU's High-Performance Materials Institute.
The National High Magnetic Field Laboratory is the world’s largest and highest-powered magnet facility. Located at Florida State University, the University of Florida and Los Alamos National Laboratory, the interdisciplinary National MagLab hosts scientists from around the world to perform basic research in high magnetic fields, advancing our understanding of materials, energy and life. The lab is funded by the National Science Foundation (DMR-1157490) and the state of Florida. For more information, visit us online at nationalmaglab.org or follow us on Facebook, Twitter, Instagram and Pinterest at NationalMagLab.