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    Category Chemistry/Nanotechnology

    In the fast lane: Conductive Electrodes are key to Fast-Charging Batteries

    July 10, 2017, Categories  Physics, Technology/Electronics, Chemistry/Nanotechnology

    Drexel University researchers have developed two new electrode designs, using MXene material, that will allow batteries to charge much faster. The key is a microporous design that allows ions to quickly make their way to redox active sites. Credit: Drexel University

    Drexel University researchers have developed two new electrode designs, using MXene material, that will allow batteries to charge much faster. The key is a microporous design that allows ions to quickly make their way to redox active sites. Credit: Drexel University

    Researchers use mxene to push charging rate limits in energy storage. Can you imagine fully charging your cell phone in just a few seconds? Researchers in Drexel University’s College of Engineering can, and they took a big step toward making it a reality with their recent work unveiling of a new battery electrode design...

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    Breakthrough in Spintronics

    July 10, 2017, Categories  Physics, Technology/Electronics, Chemistry/Nanotechnology

    1, Bismuthene film interrupted at a step in the silicon carbide substrate viewed through a scanning tunnelling microscope. The film areas inevitably end at the substrate step and a conducting edge channel (white) occurs. 2. Schematic illustration of the conducting edge channels at the boundaries of the bismuthene film. The edge channels protect the spins against scattering and thereby allow loss-free and efficient spin-based data transmission.

    1, Bismuthene film interrupted at a step in the silicon carbide substrate viewed through a scanning tunnelling microscope. The film areas inevitably end at the substrate step and a conducting edge channel (white) occurs.
    2. Schematic illustration of the conducting edge channels at the boundaries of the bismuthene film. The edge channels protect the spins against scattering and thereby allow loss-free and efficient spin-based data transmission.

    It’s ultra-thin, electrically conducting at the edge due to quantum effects and insulating within – and all that at room temperature: Physicists from the University of Würzburg have developed a promising new material. The material class of topological insulators is presently the focus of international solids research...

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    Gold Remembers: ‘Shape Memory’ Effect Demonstrated in Gold Particles

    July 9, 2017, Categories  Technology/Electronics, Chemistry/Nanotechnology, Physics

    Self-Healing and Shape Memory Effects in Gold Microparticles through the Defects-Mediated Diffusion. Advanced Science, 2017; 1700159 DOI: 10.1002/advs.201700159

    Self-Healing and Shape Memory Effects in Gold Microparticles through the Defects-Mediated Diffusion. Advanced Science, 2017; 1700159 DOI: 10.1002/advs.201700159

    Researchers from the Technion-Israel Institute of Technology and Germany have demonstrated for the first time the phenomena of shape memory and self-healing in gold microparticles. Achieved through defects-mediated diffusion in the particle, the discovery could one day lead to development of micro- and nano-robots capable of self-repair; mechanically stable and damage-tolerant components and devices; and targeted drug delivery.

    Shape-memory materials are characterized by the ability to repair the damage caused to them (such as plastic deformation) and to recover their original shape...

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    Iron Secrets behind Superconductors unlocked

    July 8, 2017, Categories  Physics, Technology/Electronics, Chemistry/Nanotechnology

    This illustration is based on a theoretical understanding of microscope-based measurements carried out by Cornell Univrsity. It shows a 2-dimensional iron-layer. The lattice seen here rougly measures 10/1.000.000 of 1 millimeter on each side. The red and darkblue clover-like structures represent two diffent iron electrons - each individually expressed (orbital state). In order to arrive at superconductivity the electrons must form groups of two (Cooper pairing) - symbolized by the light blue 'eclipses'. They are superconductive - while the red do not form Cooper pairs because they predominantly contribute to the upholding of magnetism in the entire system. The scientific article from Niels Bohr Institute, Cornell University, University of St. Andrews et.al. demonstrates for the first time ever, that the five unbound iron electrons behave fundamentally different during the state of superconductivity. Illustration: Cornell University

    This illustration is based on a theoretical understanding of microscope-based measurements carried out by Cornell Univrsity. It shows a 2-dimensional iron-layer. The lattice seen here rougly measures 10/1.000.000 of 1 millimeter on each side. The red and darkblue clover-like structures represent two diffent iron electrons – each individually expressed (orbital state). In order to arrive at superconductivity the electrons must form groups of two (Cooper pairing) – symbolized by the light blue ‘eclipses’. They are superconductive – while the red do not form Cooper pairs because they predominantly contribute to the upholding of magnetism in the entire system. The scientific article from Niels Bohr Institute, Cornell University, University of St. Andrews et.al...

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