Carbon Nanotubes and Other Nanostructured Materials Originally delivered Jul 28, 2011 Developed by: VLS - Virtual Local Section Type: Archived WebinarLevel: Advanced Duration: 1 hour PDHs: 1.00 Share This Post: Preview Webinar: The discovery of fullerenes in 1985 sparked the interest of researchers in novel crystalline forms of carbon. Nobel laureate Richard Smalley, co-discoverer of fullerenes, was a strong advocate of carbon nanotube research and his endorsement strengthened the field. The results of such an extensive effort quickly demonstrated the unique properties of these carbon structures, as well as a cornucopia of potential applications in many fields of technology.The unique properties of carbon nanotubes are due to their distinctive structure, which is composed of C-C bonds more closely related to those in graphite than to those in diamond. Fullerenes, graphene, and nanotubes also have carbon bonds with sp2 hybridization as graphite. The well-known strength of carbon nanotubes is related to the intrinsic strength of the sp2 carbon-carbon bonds. Young's modulus values near 1,000 GPa have been predicted or measured on individual nanotubes or nanotubes ropes. This is around 50 times higher than the modulus of steel, which coupled with their light weight make carbon nanotubes an attractive filler for high-strength composites.The electronic properties of carbon nanotubes are also astounding. Depending on their geometric structure they can either be metallic or semiconducting since, as discussed below, slight changes in the geometric configuration can result in significant changes in electronic structure. This offers materials scientists the opportunity to design -- at the nano-scale -- the best material for each specific application.Many of the potential applications of Nanotubes are still limited by the complexity involved in their synthesis, dispersion, and manipulation at the industrial scale. These are all areas in which the involvement of Chemical Engineers with background in catalysis, reactor design, separation processes, and colloidal chemistry is highly valuable. Presenter(s): Daniel Resasco Daniel E. Resasco is a Professor of Chemical, Biological, and Materials Engineering at the University of Oklahoma. He holds the D. Bourne endowed Chair. He received his PhD from Yale University in 1983. He is author of more than 190 publications and 30 industrial patents in the areas of heterogeneous catalysis and carbon nanotubes. He has been a Presidential Professor, S. Wilson Professor, and in the last few years he was awarded the Oklahoma Chemist of the Year award by the American Chemical Society, the Yale Science and Engineering Association award, and the Regents Award for Superior...Read more Once the content has been viewed and you have attested to it, you will be able to download and print a certificate for PDH credits. If you have already viewed this content, please click here to login. Checkout Checkout Do you already own this? Log In for instructions on accessing this content. Pricing AIChE Member Credits 0.5 AIChE Members $69.00 AIChE Undergraduate Student Members Free AIChE Graduate Student Members Free Virtual Local Section Members Free Non-Members $99.00 Webinar content is available with the kind permission of the author(s) solely for the purpose of furthering AIChE’s mission to educate, inform and improve the practice of professional chemical engineering. All other uses are forbidden without the express consent of the author(s).