Applied physics professor Chris Marianetti figures out how to shatter the world's strongest material
New York, NY November 29, 2010 In 2008, experiments at The Fu Foundation School of Engineering and Applied Science at Columbia University established pure graphene, a single layer of graphite only one atom thick, as the strongest material known to mankind. This raised a question for Chris Marianetti, Assistant Professor in Columbia Engineering's Department of Applied Physics and Applied Mathematics: how and why does graphene break?
Using quantum theory and supercomputers, Marianetti has revealed the mechanisms of mechanical failure of pure graphene under tensile stress. In a paper recently accepted for publication in the journal Physical Review Letters, he shows that, when graphene is subject to strain equal in all directions, it morphs into a new structure which is mechanically unstable.
Marianetti says this failure mechanism is a novel soft-mode phonon instability. A phonon is a collective vibrational mode of atoms within a crystal, similar to a wave in a liquid.
Marianetti added that this is the first time a soft optical phonon has ever been linked to mechanical failure and that therefore it is likely that this novel failure mechanism is not exclusive to graphene but may be prevalent in other very thin materials. "With nanotechnology becoming increasingly ubiquitous, understanding the nature of mechanical behavior in low dimensional systems such as graphene is of great importance. We think strain may be a means to engineer the properties of graphene, and therefore understanding its limits is critical." The research was funded by the National Science Foundation.
Marianetti's research interests lie in the use of classical and quantum mechanics to model the behavior of materials at the atomic scale. In particular, he is focused on applying these techniques to materials with potential for energy storage and conversion. Current applications in his research program range from nuclear materials such as plutonium to rechargeable battery materials such as cobalt oxides. ###
Marianetti received his BS and MS degrees from Ohio State University and his PhD in materials science and engineering from MIT. Before joining the faculty at Columbia Engineering, he did post-doctoral research in the Department of Physics at Rutgers University and in the Materials Chemistry Division of Lawrence Livermore National Laboratory.
Columbia Engineering
Columbia University's Fu Foundation School of Engineering and Applied Science offers programs to both undergraduate and graduate students who undertake a course of study leading to the bachelor's, master's, or doctoral degree in engineering and applied science. With facilities specifically designed and equipped to meet the laboratory and research needs of faculty and students, Columbia Engineering is home to a broad array of basic and advanced research installations, from the Columbia Center for Electron Transport in Molecular Nanostructures to the Columbia Genome Center. These interdisciplinary centers in science and engineering, materials research, nanoscale research, and genomic research are leading the way in their respective fields while individual groups of engineers and scientists collaborate to solve some of society's more vexing challenges. www.engineering.columbia.edu/
Contact: Holly Evarts holly@engineering.columbia.edu 212-854-3206 Columbia University
No comments:
Post a Comment