Two materials engineers, Evan Reed and Mitchell Ong from the Stanford School of Engineering, have described a novel method of engineering piezoelectrics into graphene in a paper reported in ACS Nano.
A research team comprising Mihaela Leonida and colleagues from the Fairleigh Dickinson University has explained the preparation technique of chitosan nanoparticles in the International Journal of Nano and Biomaterials.
A research team from the University of California- Los Angeles (UCLA) has developed novel graphene-based electrodes with higher conductivity and surface area utilizing a typical LightScribe DVD optical drive.
A research team led by Tilman Esslinger from the Institute of Quantum Electronics at ETH Zurich is one of the two groups to successfully simulate graphene in experiments. This technique will help understand the consequences caused by the modification of nanomaterial’s lattice structure.
A team of international researchers led by Professor Tim Liedl, a LMU physicist, has developed novel, optically active, three-dimensional structures based on the structure of DNAs. DNA strands act as scaffolds for bonding gold nanoparticles in predestined patterns.
Twin Creeks Technologies, a provider of thin crystalline wafer manufacturing equipment for the semiconductor and solar industries, has launched the Hyperion production system for manufacture of ultra-thin wafers.
Scientists from the Department of Energy's SLAC National Accelerator Laboratory in US and Stanford University have developed a system of "designer electrons".
A research team led by Chongmin Wang, a materials scientist at the Department of Energy's Pacific Northwest National Laboratory (PNNL), has conducted a study on a new silicon-carbon nanocomposite electrode material.
A research team comprising scientists from the Mitsubishi Electric Research Laboratories and Duke University has put forward a theory that the efficacy of wireless power transfer systems can be improved by increasing their inductive coupling through the integration of superlens, a lens made of artificially-structured metamaterials.
A research team comprising Kirill Bolotin, A.K.M. Newaz, Sokrates Pantelides, Bin Wang and Yevgeniy Puzyev from the Vanderbilt University has confirmed that charged impurities present in graphene are the source of interference, and slow down the electron flow through the nanomaterial-based devices.
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