Researchers from the South Dakota State University (SDSU) have used a pyrolysis process to transform plant materials such as corn stover, native grasses and dried distillers grain solids (DDGS) into bio-oil and biochar, which could then be converted into graphene.
Scientists at Stanford University have discovered that when perovskite, a crystalline material, is stacked on top of a conventional silicon solar cell, it provides a big boost to the efficiency of the solar cell.
Picosun Oy, the leading manufacturer of high quality Atomic Layer Deposition (ALD) equipment for global industries, provides the ALD tools and solutions for industrial scale-up of 10 nm node microprocessors, power electronics, and printed sensors for automotive, medical, and environmental monitoring applications.
Researchers at Ecole polytechnique fédérale de Lausanne (EPFL), along with their collaborators have demonstrated the ability of graphene to convert a single photon into multiple electrons that possess energy that is sufficient enough for driving an electrical current. The team used an advanced spectroscopic method for this demonstration. This discovery holds great promise for development of future photovoltaic devices.
An engineering team from the Kansas State University has unveiled certain vital properties of graphene oxide, which can enhance flexible batteries made of sodium and lithium-ions.
Scientists at EPFL have developed a simple and innovative method to make nanowires from perovskite material, which could aid in enhancing the efficiency of solar cells.
A team of researchers from UK and China have designed a novel sulfur cathode wrapped with graphene for rechargeable lithium-sulfur batteries. Dr. Vasant Kumar from the University of Cambridge and Professor Renjie Chen from the Beijing Institute of Technology have led the research team in this project.
A team of researchers in Spain have developed a method to generate a powerful magnetic field by intercalating lead atoms on a graphene sheet. The team included researchers from IMDEA Nanoscience, the University of the Basque Country, the Madrid Institute of Materials Science (CSIC) and the Autonomous University of Madrid.
A research team from Rice University has succeeded in developing flexible multilayer graphene sheets, by patterning inexpensive polyimide sheets with a computer-controlled laser.
Scientists at the University College London (UCL) have used supercomputer simulations to develop a ‘virtual lab’ for designing new nanocomposite materials. James Suter, Peter Coveney and Deren Groen based in UCL’s Centre for Computational Science have collaborated to develop the ‘virtual lab’.
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