Headline: AI speeds up the discovery of energy and quantum materials
■ Release Date: 2024.10.7
■ Published by: Tohoku University
■ Keywords: energy, solar cells, photovoltaic
■ Abstract:
Unearthing new LEDs, solar cells, and photodetectors requires extensive knowledge surrounding the optical properties of materials. Calculating these takes time and resources. Yet researchers unveiled a new AI tool that can accurately, and crucially much faster than quantum simulations, for predicting optical properties.
Headline: Stopping off-the-wall behavior in fusion reactors
■ Release Date: 2024.10.7
■ Published by: DOE/Princeton Plasma Physics Laboratory
■ Keywords: boron, plasma, tungsten
■ Abstract:
New experimental results suggest that sprinkling boron into a tokamak could shield the wall of the fusion vessel and prevent atoms from the wall from getting into the plasma. A new computer modeling framework shows the boron powder may only need to be sprinkled from one location.
Headline: A novel method to split water to create hydrogen -- a clean source of fuel
■ Release Date: 2024.10.7
■ Published by: Tohoku University
■ Keywords: hydrogen, fuel, cocatalyst
■ Abstract:
Researchers have developed a novel method using facet-selective, ultrafine cocatalysts to efficiently split water to create hydrogen -- a clean source of fuel.
Headline: New polymer design breaks the tradeoff between toughness and recyclability
■ Release Date: 2024.10.7
■ Published by: Osaka University
■ Keywords: catalyst, polymer, plastics
■ Abstract:
Researchers have created a high-performance polymer that can be chemically recycled without compromising its heat and chemical resistance. The revolutionary design includes a directing group that allows links in the polymer to be broken easily with a catalyst and the original polymer to be reformed in few steps. The directing group could be included in many polymers, potentially providing a new generation of high-performance plastics that can be recycled indefinitely.
Headline: Atomic-level mechanism in polycrystalline materials
■ Release Date: 2024.10.8
■ Published by: University of California - Irvine
■ Keywords: polycrystalline materials, platinum, nanocrystalline
■ Abstract:
Researchers show that for the first time they have achieved atomic-scale observations of grain rotation in polycrystalline materials. Using state-of-the-art microscopy tools, the scientists were able to heat samples of platinum nanocrystalline thin films and observe the mechanism driving grain rotation in unprecedented detail.
Headline: New insights into ammonia decomposition
■ Release Date: 2024.10.8
■ Published by: Ruhr-University Bochum
■ Keywords: ammonia, hydrogen, nitrogen
■ Abstract:
Using ammonia is regarded as a promising method of transporting hydrogen. However, an efficient process is also needed to convert it back into hydrogen and nitrogen.
Headline: Solar-powered desalination system requires no extra batteries
■ Release Date: 2024.10.8
■ Published by: Massachusetts Institute of Technology
■ Keywords: batteries, solar, desalination
■ Abstract:
Engineers built a solar-powered desalination system that produces large quantities of clean water despite variations in sunlight throughout the day. Because it requires no extra batteries, it offers a much more affordable way to produce drinking water, compared to other solar-driven designs.
Headline: Heavy metals in the ocean become more toxic
■ Release Date: 2024.10.9
■ Published by: Helmholtz Centre for Ocean Research Kiel (GEOMAR)
■ Keywords: heavy metals, lead, mercury
■ Abstract:
Toxic trace elements such as lead, mercury, arsenic, and cadmium naturally occur in small quantities in coastal seas. However, human activities, such as industry and agriculture, contribute significantly larger amounts. A new study has examined how climate change already affects the distribution and accumulation of these elements and how it could impact them in the future. One of the findings: Climate-related natural events are releasing more contaminants, which pose a risk to both human and animal health. However, there is still insufficient knowledge about how these contaminants will behave in the future.
