Scientists have captured the first real-time nanoscale images of lithium dendrite structures known to degrade lithium-ion batteries.
EPFL researchers have shed new light on the fundamental mechanisms of heat dissipation in graphene and other two-dimensional materials. They have shown that heat can propagate as a wave over very long distances. This is key information for engineering the electronics of tomorrow.
A team of Harvard scientists has developed an entirely new, highly versatile mechanism for controlling passage of materials through micropores, using fluid to modulate their opening and closing.
Scientists at Technische Universität Dresden have now been able to add another piece to the puzzle of cell biological mechanisms, as they report in the latest issue of the renowned scientific journal Cell on March 5, 2015.
Nanoparticles can function as carriers for medicines to combat lung cancer: working in a joint project, scientists from the Helmholtz Zentrum München and the Ludwig-Maximilians-Universität in Munich have developed nanocarriers that site-selectively release medicines/drugs at the tumor site in human and mouse lungs. In the journal, ACS Nano, the scientists reported that this approach led to a significant increase in the effectiveness of current cancer medicines in lung tumor tissue.
A new paint that makes robust self-cleaning surfaces has been developed by a team led by UCL researchers. The coating can be applied to clothes, paper, glass and steel and when combined with adhesives, maintains its self-cleaning properties after being wiped, scratched with a knife and scuffed with sandpaper.
A method to selectively enhance or inhibit optical nonlinearities in a chip-scale device has been developed by scientists, led by the University of Sydney. The researchers from the Centre for Ultrahigh bandwidth Devices for Optical Systems, based at the University of Sydney, Australia, published their results in Nature Communications today.
This technology reaches nearly 10 terahertz, the highest frequency manufactured in CMOS.
Just weeks after NSLS-II achieved first light, a team of scientists at the X-Ray Powder Diffraction beamline tested a setup that yielded data on thermoelectric materials and resulted in science published in Applied Physics Letters - Materials.
Magnetic vortex structures, so-called skyrmions, could in future store and process information very efficiently. They could also be the basis for high-frequency components. For the first time, a team of physicists succeeded in characterizing the electromagnetic properties of insulating, semiconducting and conducting skyrmion-materials and developed a unified theoretical description of their behavior. This lays the foundation for future electronic components with purpose-designed properties.