The Oklahoma-Arkansas MRSEC hosted the14th SIMC conference which engaged international participation from a diverse group of more than 30 nations. The technical sessions presented over 5 days with parallel sessions encompassed the transfer of many new and developing ideas, and the talks received the highest evaluation as indicated by the results of the conference survey.
The explosion of interest in graphene, a single layer of carbon atoms, has called attention to the advantages of materials with small effective masses. In our InSb quantum wells, the electron effective mass is as small as in graphene while the room-temperature
The IRG on ferroelectric nanophotonic materials and devices seeks to develop tunable photonic devices by combining the nonlinear dispersion of photonic metamaterials with the unusual optical properties of ferroelectric perovskites. A series of experimental tests and theoretical calculations have demonstrated the potential of this approach.
When proteins are made inside cells, genetic information (in the form of messenger RNA) must be "translated" into specific sequences of amino acid building blocks. Accurate translation is essential to the health of the cell, and the idea that "one gene gives one protein" emerged very early in the development of the field of molecular biology.
Marni Goldman, Education Director of CPIMA, died of natural causes in late February while on vacation with her family. Although she never walked and had only the most limited use of her arms, Marni's academic and professional accomplishments placed her in elite company, even as her friendships extended far and wide.
Susan J. Muller, University of California Berkeley, and Eric S.G. Shaqfeh, Stanford Highlight from Stanford MRSEC 0213618
Mike McGehee, Stanford University, Robert D. Miller, IBM Almaden Research Center, Joe DeSimone, University of North Carolina Highlight from Stanford MRSEC 0213618
Â’ Nanoscale metallic structures are promising platforms for sensors: using photons to launch surface plasmon "polaritons", metallic nanowires can guide and re-emit light over tens of microns. The re-emission of light at the other end of a nanowire can be promoted or altered by adsorption of molecules.
Researchers at Yale University have invented a high-performance material for future generations of transistors and devices. New oxide materials are required to make faster computer chips for the future. These new oxides will replace the oxide that has been the standard for the last 50 years, silicon dioxide.
