An international research team led by Chinese and American scientists has developed high-strength, super-tough sheets of carbon that can be inexpensively fabricated at low temperatures.
The team reported on Monday in the Proceedings of the National Academy of Sciences the sheets they made by chemically stitching together platelets of graphitic carbon, which is similar to the graphite found in the soft lead of an ordinary pencil.
The fabrication process resulted in a material whose mechanical properties exceed those of carbon fiber composites that are currently used in diverse commercial products.
“These sheets might eventually replace the expensive carbon fiber composites that are used for everything from aircraft and automobile bodies to windmill blades and sports equipment,” said Ray Baughman, professor of chemistry at University of Texas.
Carbon fiber composites are expensive in part because carbon fibers are produced at extremely high temperatures, which can exceed 2,500 degrees Celsius.
“In contrast, our process can use graphite that is cheaply dug from the ground and processed at temperatures below 45 degrees Celsiu,” said Cheng Qunfeng, professor of chemistry at China’s Beihang University.
According to Cheng, graphite consists of platelets made up of stacked layers of graphene. Graphene is simply a single layer of carbon atoms, arranged in a pattern that looks like a chicken wire mesh fence, where each hexagon in the mesh is formed by six carbon atoms.
“While scientists can continuously make large sheets of graphene by high-temperature processing, and have shown these sheets to have remarkable strength, it is impractical to make thick plates of graphite by merely stacking large-area graphene sheets,” Cheng said. “One would need to stack about 150,000 graphene sheets to make a graphite sheet having about the thickness of a human hair.”
The researchers found inspiration in natural nacre, also known as mother-of-pearl, which gives some seashells their strength and toughness. Nacre is composed of parallel platelets that are bound together by thin layers of organic material, similar to the way bricks in a wall are held together by mortar.
“Instead of mechanically stacking large-area graphene sheets, we oxidize micron-size graphite platelets so that they can be dispersed in water, and then filter this dispersion to inexpensively make sheets of oriented graphene oxide,” Baughman said. “This process is akin to hand-making sheets of paper by filtering a slurry of fibers.”
“At this stage, the sheets are neither strong nor tough, meaning they cannot absorb much energy before rupturing,” said Baughman.
“The trick we use is to stitch together the platelets in these sheets using sequentially infiltrated bridging agents that interconnect overlapping neighboring platelets, and convert the oxidized graphene oxide to graphene,” said Baughman.
The key to this advance is that the bridging agents separately act via formation of covalent chemical bonds and van der Waals bonds, according to Baughman.
Sheets that incorporated the bridging agents were 4.5 times stronger and 7.9 times tougher than agent-free sheets, said Wan Sijie, a Beihang University PhD student.
“While sheets of expensive carbon fiber composites can provide a similar strength in all sheet-plane directions, the energy that they can absorb before fracture is about one-third that of our sequentially bridged graphene sheets,” said Wan.
“Because our sheets are fabricated at low temperatures, they are low cost. In addition to exhibiting high sheet strength, toughness and fatigue resistance, they have high electrical conductivity and are able to shield against electromagnetic radiation,” said Wan.