Researchers create a transparent composite plastic as strong as steel
By Darren Quick
October 21, 2007
October 22, 2007 Researchers at the University of Michigan have created a light-weight, transparent composite plastic that’s as strong as steel. The material mimics the brick-and-mortar molecular structure of mother of pearl, the iridescent lining of mussel and oyster shells, which is built layer by layer and is one of the toughest natural mineral based materials.
The interdisciplinary team of scientists solved a problem that has confounded engineers and scientists for decades: individual nano-size building blocks such as nanotubes, nanosheets and nanorods are ultrastrong, but larger materials made out of bonded nano-size building blocks were comparatively weak - until now. "When you tried to build something you can hold in your arms, scientists had difficulties transferring the strength of individual nanosheets or nanotubes to the entire material," Engineering professor Nicholas Kotov said. "We've demonstrated that one can achieve almost ideal transfer of stress between nanosheets and a polymer matrix." The researchers created this new composite plastic with a machine they developed that builds materials one nanoscale layer after another. The robotic machine consists of an arm that hovers over a wheel of vials of different liquids. In this case, the arm held a piece of glass about the size of a stick of gum on which it built the new material. The arm dipped the glass into the glue-like polymer solution and then into a liquid that was a dispersion of clay nanosheets. After those layers dried, the process repeated. It took 300 layers of each the glue-like polymer and the clay nanosheets to create a piece of this material as thick as a piece of plastic wrap.
The glue-like polymer used in this experiment, which is polyvinyl alcohol, was as important as the layer-by-layer assembly process. The structure of the "nanoglue" and the clay nanosheets allowed the layers to form cooperative hydrogen bonds, which gives rise to what Kotov called "the Velcro effect." Such bonds, if broken, can reform easily in a new place. The Velcro effect is one reason the material is so strong. Another is the arrangement of the nanosheets. They're stacked like bricks, in an alternating pattern. "When you have a brick-and-mortar structure, any cracks are blunted by each interface," Kotov explained. "It's hard to replicate with nanoscale building blocks on a large scale, but that's what we've achieved."
Kotov almost dubbed the new material "plastic steel," but the new material isn't quite stretchy enough to earn that name. Nevertheless, he says its further development could lead to lighter, stronger armor for soldiers or police and their vehicles. Indeed the potential applications for this type of material seem huge - it could also be used in microelectromechanical devices, microfluidics, biomedical sensors and valves and unmanned aircraft, maybe even in cars to make blindspots a thing of the past.
Kotov and other U-M faculty members are authors of a paper on this composite material, "Ultrastrong and Stiff Layered Polymer Nanocomposites," published in Science (Volume 318, Issue 5847, Pages 80-83, October 5, 2007).