Researchers at University of California, Santa Barbara, in collaboration with Rice University, have recently demonstrated a rapid synthesis technique for large-area Bernal (or AB) stacked bilayer graphene films that can open up new pathways for digital electronics and transparent conductor applications.
A University of Arizona-led team of physicists has discovered how to change the crystal structure of graphene, more commonly known as pencil lead, with an electric field, an important step toward the possible use of graphene in microprocessors that would be smaller and faster than current, silicon-based technology.
Research and Markets has announced the addition of the "The Global Market for Graphene to 2020" report to their offering.
Mason Graphite Inc. ("Mason Graphite" or the "Company") has completed the second tranche of its investment in Group NanoXplore Inc. ("NanoXplore") by investing $350,000 for an additional 20% interest in NanoXplore.
When silicon became the medium of choice for semiconductors in the 60's, the previous material, germanium, was left behind to the point where few today have ever heard of it. With the rise of graphene, silicon may eventually experience the same fate, relegated to a curiosity at some semiconductor museum.
There is no disputing graphene is strong. But new research by Rice University and the Georgia Institute of Technology should prompt manufacturers to look a little deeper as they consider the miracle material for applications.
Canada Carbon Inc. (the "Company") is pleased to present these Scanning Electron Microscope (SEM) images of its Miller hydrothermal graphite crystals, provided to it by the El Segundo, California laboratories of Evans Analytical Group. These micrographs clearly reveal the highly crystalline nature of the Miller graphite, evidenced by both the platy shapes of the crystals, and their highly organized layered structure, in a way that is now clearly visible to the naked eye.
In a first-of-its-kind study of how a material some think could transform the electronics industry moves in water, researchers at the University of California, Riverside Bourns College of Engineering found graphene oxide nanoparticles are very mobile in lakes or streams and therefore likely to cause negative environmental impacts if released.
The isolation of graphene at the University in 2004 led to the discovery of many other 2D crystals. While graphene has an unrivalled set of superlatives, these crystals cover a large range of properties: from the most conductive to isolating, from transparent to optically active.
An international team of scientists, led by physicists at the University of Arkansas, has tracked the dynamic movement of ripples in freestanding graphene at the atomic level.
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