News Release

Process to transition two-layer graphene into diamond-hard material on impact discovered

The innovation could enable development of a range of flexible, impenetrable materials capable of protecting the body and fragile objects

Peer-Reviewed Publication

Advanced Science Research Center, GC/CUNY

Diamene Study

image: By applying pressure at the nanoscale with an indenter to two layers of graphene, each one-atom thick, CUNY researchers transformed the honeycombed graphene into a diamond-like material at room temperature.  view more 

Credit: Ella Maru Studio

NEW YORK, (Dec. 18, 2017) -- Imagine a material as flexible and lightweight as foil that becomes stiff and hard enough to stop a bullet on impact. In a newly published paper in Nature Nanotechnology, researchers across The City University of New York (CUNY) describe a process for creating diamene: flexible, layered sheets of graphene that temporarily become harder than diamond and impenetrable upon impact.

Scientists at the Advanced Science Research Center (ASRC) at the Graduate Center, CUNY, worked to theorize and test how two layers of graphene -- each one-atom thick -- could be made to transform into a diamond-like material upon impact at room temperature. The team also found the moment of conversion resulted in a sudden reduction of electric current, suggesting diamene could have interesting electronic and spintronic properties. The new findings will likely have applications in developing wear-resistant protective coatings and ultra-light bullet-proof films.

"This is the thinnest film with the stiffness and hardness of diamond ever created," said Elisa Riedo, professor of physics at the ASRC and the project's lead researcher. "Previously, when we tested graphite or a single atomic layer of graphene, we would apply pressure and feel a very soft film. But when the graphite film was exactly two-layers thick, all of a sudden we realized that the material under pressure was becoming extremely hard and as stiff, or stiffer, than bulk diamond."

Angelo Bongiorno, associate professor of chemistry at CUNY College of Staten Island and part of the research team, developed the theory for creating diamene. He and his colleagues used atomistic computer simulations to model potential outcomes when pressurizing two honeycomb layers of graphene aligned in different configurations. Riedo and other team members then used an atomic force microscope to apply localized pressure to two-layer graphene on silicon carbide substrates and found perfect agreement with the calculations. Experiments and theory both show that this graphite-diamond transition does not occur for more than two layers or for a single graphene layer.

"Graphite and diamonds are both made entirely of carbon, but the atoms are arranged differently in each material, giving them distinct properties such as hardness, flexibility and electrical conduction," Bongiorno said. "Our new technique allows us to manipulate graphite so that it can take on the beneficial properties of a diamond under specific conditions."

The research team's successful work opens up possibilities for investigating graphite-to-diamond phase transition in two-dimensional materials, according to the paper. Future research could explore methods for stabilizing the transition and allow for further applications for the resulting materials.

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This work was funded by the BES Office of the Department of Energy and the complete list of authors includes Yang Gao, Tengfei Cao, Filippo Cellini, Claire Berger, Walt Heer, Erio Tosatti, Angelo Bongiorno and Elisa Riedo.

For a copy of this paper and images, contact Paul McQuiston at 212-413-3307, paul.mcquiston@asrc.cuny.edu. For media inquiries, please contact Tanya Domi, 212-817-7283, tdomi@gc.cuny.edu, or Paul McQuiston 212-413-3307, paul.mcquiston@asrc.cuny.edu.

About the Advanced Science Research Center at the Graduate Center, CUNY

The Advanced Science Research Center (ASRC) at the Graduate Center of the City University of New York (CUNY) elevates scientific research and education at CUNY and beyond through initiatives in five distinctive, but increasingly interconnected, disciplines: environmental sciences, nanoscience, neuroscience, photonics, and structural biology. The ASRC promotes a collaborative, interdisciplinary research culture with researchers from each of the initiatives working side by side in the ASRC's core facilities, sharing equipment that is among the most advanced available.


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