Forscher vom Fraunhofer-Institut für Werkstoffmechanik IWM in Freiburg haben nun mit einer aufwendigen Computersimulation gezeigt, dass nanokristalline Schichten die Reibung zwar reduzieren, dass es aber dennoch zum Verschleiss kommen kann.
A new phase of matter known as topological insulators, until recently known only for esoteric quantum-mechanical properties, might have a practical use in controlling magnetic memory and logic devices.
Adding to the growing fundamental understanding of the machinery of muscle cells, a group of biophysicists describe how actin filaments are stabilized at one of their ends to form a basic muscle structure called the sarcomere.
Scientists have developed a new nanoscale agent for imaging the gastrointestinal (GI) tract. This safe, noninvasive method for assessing the function and properties of the GI tract in real time could lead to better diagnosis and treatment of gut diseases.
Traditionally, zeolites have been derived from inorganic material like silicon or aluminum. Now, researchers have devised a way to synthesize large-pore crystalline polyimide covalent organic frameworks.
Dr Felice Torrisi, University Lecturer in Graphene Technology, has been awarded a Young International Researchers' Fellowship from the National Science Foundation of China to look at how graphene and two-dimensional materials could enable printed and flexible eyes.
Governor Andrew M. Cuomo today announced that the U.S. Army Corps of Engineers has issued a Section 404 permit for the Marcy Nanocenter site, enabling the next phase of the Nano Utica initiative. This includes the construction of a 450 MM enabled wafer fabrication campus.
The discovery of a new material combination that could lead to a more efficient approach to computer memory and logic is the first promising indication that it may be possible to build a practical technology with a novel material known as a 'topological insulator'. The research team's results show that such a scheme can be 10 times more efficient for controlling magnetic memory or logic than any other combination of materials measured to date.
A UCF spinout company is at the forefront of perfecting specialized nanotechnology designed to extend the longevity of batteries and superconductors. Batteries will be lighter, stay charged longer and need to be replaced less frequently - and that's a win for our smart phones and our environment.