A research team of Dr. James Tour’s lab at Rice University has developed a novel method to bond different organic molecules to graphene sheets, making the wonder material suitable for numerous organic chemistry applications.
North Carolina State University researchers have devised a novel technique for fabricating elastic conductors using carbon nanotubes, paving the way for commercial production of stretchable conductors for applications in a new generation of stretchable electronic devices.
A research team headed by scientists at the University of California, Riverside has discovered that a bilayer graphene sheet becomes an insulating material when its electron count comes down to zero, paving the way to use the wonder material as an electronic material in the electronics and semiconductor applications.
Composite materials can withstand tremendous stress, which makes them useful in everything from pipes to speedboats to pedestrian bridges. But exactly how much can these materials actually tolerate? A project with fundin...
QuesTek Innovations LLC has been awarded a Small Business Innovation Research (SBIR) Phase II project from the Defense Advanced Research Projects Agency (DARPA) to apply QuesTek's Materials by Design technology to de...
A critical review of claims that there are materials harder than diamond.
Paul Scherrer Institute’s researchers have succeeded in accurately understanding how a material’s magnetic structure changes. The study was conducted using cupric oxide or CuO. First the material was subjected to a laser pulse, then short X-ray pulses helped obtain almost instantaneous images of several points in time for separate interim steps during the structure change process.
Scientists from the Niels Bohr Institute have developed a novel laser cooling method for semiconductor membranes, paving the way to develop efficient cooling systems for components of future ultrasensitive sensors and quantum computers.
A research team from the Eindhoven University of Technology (TU/e) has demonstrated that a molecular self-assembly process is capable of following various pathways, thus producing different structures.
A research team led by Kit S. Lam from UC Davis has synthesized a novel class of nanoparticles to eliminate premature release of drugs, paving the way to deliver anti-cancer drugs to tumor sites accurately and efficiently.
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