Articles tagged with Atomic Diffusion
Researchers developed Cu/Zn solid-solution phase hosts to overcome electrochemical limitations in multivalent metal ion batteries. The material's layered crystal structure and abundant interlayer confined species provide favorable diffusion pathways for charge carriers.
Researchers have successfully mass-produced aluminum nanowires using a novel atomic diffusion technique, paving the way for mass production of high-performance nanodevices in fields like sensing devices and optoelectronics. The new method enables precise control over NW growth, leading to significant improvements in quality and purity.
Scientists studied the nickel-tungsten alloy interface to understand its properties and behavior. The research revealed the formation of intermetallic compounds and diffusion-induced recrystallization regions, which significantly impact the material's mechanical, thermal, and chemical properties.
By recasting diffusion as a sum of individual contributions called 'kinosons,' researchers developed a new method to model alloy behavior. Machine learning is used to compute the statistical distribution of these contributions, allowing for fast and accurate simulation of diffusion. This breakthrough enables significant improvements in...
A new study at BESSY II has provided deeper insights into the ordering processes and diffusion phenomena in High-Entropy Alloys. The team analysed samples of a Cantor alloy, revealing local atomic structures using element-specific EXAFS and Reverse Monte Carlo analysis.
Researchers at Hokkaido University have discovered a mechanism for carbon atoms to come together on the surface of interstellar ice grains, producing complex organic molecules. This process occurs at temperatures above 30 Kelvin and may have played a role in the origin of life on Earth.
Scientists have captured the first atomic-scale images of tin on niobium during the growth process of next-generation particle accelerators, revealing potential for greater control over superconducting Nb3Sn films. The study aims to optimize fabrication of next-generation accelerator cavities and reduce cryogenic infrastructure costs.
Researchers have validated a new theory for molecular diffusion in polymer matrices, explaining how molecules move through complex media. The study found that temperature and molecule size significantly impact transport rates, enabling the design of more selective polymer membranes.
Researchers at TU Wien have developed a new method for creating high-quality contacts between metal and semiconductor materials, enabling faster and more efficient computer chips. The technology uses crystalline aluminium and a sophisticated silicon-germanium layer system to overcome the problem of oxygen contamination.
Scientists at Osaka University developed a new numerical technique to visualize heat flux at the atomic scale for the first time. The team found that sub-atomic stresses in solid and liquid structures determine the direction of heat flux, enabling more efficient nanoscale manufacturing.
Scientists from Japan and Denmark discovered disordered one-dimensional chains in indium telluride, which exhibit ultralow thermal conductivity. This finding confirms the chemical and physical basis of low thermal conduction in thallium selenide-type materials, advancing thermoelectric power technologies.
The new Diffusion Tensor Magnetic Resonance Imaging (DT-MRI) technology provides detailed maps of brain networks and allows for diagnosis of medical conditions like stroke, as well as assessment of neurological disorders. DT-MRI also holds promise for imaging skeletal muscles, heart, and circulatory system.