A team of researchers at Michigan Technological University has discovered an innovative approach to allow light waves to pass through a lens and protect them from being consumed.
A research team from the University of California, San Diego has demonstrated the trapping of light inside nanoscale granules of hexagonal boron nitride, a crystalline material that has fascinated researchers considerably. The team was led by physics professor, Michael Fogler.
Associate Professor Jiaxing Huang of Northwestern Engineering has developed a stable proton-conducting system using a stack of clay sheets. This is a cost-effective method and the main ingredient, clay in commonly available.
Researchers at the Department of Energy's SLAC National Accelerator Laboratory have tested a new material design that enhances the ability of inexpensive solar panels to collect solar energy and release it in the form of electricity.
Researchers at the Department of Energy’s Oak Ridge (ORNL) and Los Alamos National Laboratories have directly measured the unique property of plutonium’s variable magnetism using the neutron scattering technique.
Leica Microsystems launches the Leica DM4 M and Leica DM6 M upright microscopes for materials investigation. The systems are designed for imaging, measurement, and analysis of similar features across many samples and materials.
A team of researchers from University of California, San Diego have discovered that the squared-shaped tail of a seahorse can grasp, grip and produce more contact points with a surface compared to a cylindrical tail.
A research team led by the University of Cambridge has discovered that a single material could exhibit dual metal-insulator properties at the same time.
The European Powder Metallurgy Association (EPMA) Summer School was held this year for the first time in the UK, at the Advanced Manufacturing Research Centre in Rotherham. As part of this, Metalysis hosted a visit from members of the EPMA Summer School to provide a detailed insight into the one-step metal powder production process at its site in Rotherham.
Chemists at Professor Krzysztof Matyjaszewski’s lab at Carnegie Mellon University have developed novel methods for characterizing 3D macroporous hydrogels (3DOM hydrogels), which could enable development of new “smart” responsive materials. These materials could be used for various applications, including tissue engineering scaffolds, chemical detectors, carbon capture absorbents, and as catalysts.
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