Chinese scientists have developed a lithium metal battery that boasts an energy density of more than 700 watt-hours per kilogram and stable performance at extremely low temperatures, marking a significant advancement in the production of high-energy batteries for electric vehicles. The research paper was published on Thursday in the science journal Nature.
Chen Jun, an academician of the Chinese Academy of Sciences and vice-president of Nankai University in Tianjin, was among the researchers who led the breakthrough. Chen said the team has replaced oxygen atoms with fluorine ones. It designed and synthesized novel fluorinated hydrocarbon solvent molecules, creating a new electrolyte system based on lithium-fluorine coordination.
Contamination of ground, surface and drinking water by perfluoroalkyl and polyfluoroalkyl substances (PFAS) affects millions of people worldwide. A promising new method developed by Flinders University scientists paves the way to help remove the most difficult-to-capture variants of these persistent pollutants from water.
The research team, led by Flinders ARC Research Fellow Dr. Witold Bloch, has discovered adsorbents that effectively capture PFAS, including short-chain forms that are especially difficult to remove using existing technologies.
A research team at King’s College London has isolated a new form of aluminum—a highly abundant metal, that could provide a far cheaper and more sustainable alternative to commonly used rare earth metals. Dr. Clare Bakewell, Senior Lecturer in the Department of Chemistry, and her lab developed highly reactive aluminum molecules able to break apart tough chemical bonds. Published in Nature Communications, their work has also unlocked molecular structures that have never been observed before, which creates the potential for new kinds of reactive behavior.
The team reported the first example of a cyclotrialumane, a compound comprising three aluminum atoms arranged in a trimeric—triangular—structure. The trimeric molecule carries unprecedented reactivity as the structure is retained when dissolved into different solutions, making it robust enough for use in a range of chemical reactions. These include splitting dihydrogen and the stepwise insertion and chain growth of the 2-carbon hydrocarbon, ethene.
Metals are vital for making a whole range of commodity and fine chemicals produced in industry. However, many processes, especially catalytic ones, use expensive precious materials like platinum, which are environmentally damaging to extract.
Plant owners with a so-called green thumb often seem to have a more finely tuned sense of what their plants need than the rest of us. A new “smart lighting” system for indoor vertical farms grants this ability on a facility-wide scale, responsively meeting plants’ needs while reducing energy inefficiencies, clearing a path for indoor farms as an energy-efficient food security strategy.
The system was designed and tested in a study led by Professor of Plant Biology Tracy Lawson, who conducted the research at the University of Essex and is now a member of the Carl R. Woese Institute for Genomic Biology at the University of Illinois Urbana-Champaign. The work, published in Smart Agricultural Technology, emerged from her goal to help establish the viability of vertical farming for large-scale food production.
“One of the key aspects of [vertical farming], of course, is the energy cost associated with using LED lighting,” Lawson said. “So that’s where it all started, trying to save energy.”
Fabricating efficient photocatalysts that can be used in solar-to-fuel conversion and to enhance the photochemical reaction rate is essential to the current energy crisis and climate changes due to the excessive usage of nonrenewable fossil fuels.
Imagine being an explorer, cracking open a 10,000-year-old tomb, uncovering a priceless ancient artifact – and getting rickrolled. Our deep descendants might just get the pleasure, thanks to a Global Music Vault due to be built in Norway, featuring Microsoft’s Project Silica, a tough new data storage medium that’s never gonna give you up.
There’s a common saying that once something is on the internet, it’s there forever, and even if you delete it, it will persist in some server somewhere. But that’s demonstrably untrue – just try to find your cringey old MySpace page. Even the most secure data center is vulnerable to the increasingly common and severe environmental disasters brought on by climate change. Many will lose their data if there’s a long-term power outage, or a large-scale electromagnetic pulse from an attack or, worse still, the Sun. Even in the best-case scenario, physical storage media like Blu-Rays, archival tape, hard drives and even solid state drives will degrade in decades.
To ensure that our history lives on for longer, Microsoft has been experimenting with storing data on glass with what it calls Project Silica. In 2019, the company demonstrated the tech in a partnership with Warner Bros by writing the 1978 movie Superman onto a slide of quartz silica glass and reading it back. The slide, measuring just 75 × 75 mm (3 × 3 in) and 2 mm (0.08 in) thick, could hold as much as 75.6 GB, and remained readable even after being scratched, baked, boiled, microwaved, flooded and demagnetized.
Green hydrogen production technology, which utilizes renewable energy to produce eco-friendly hydrogen without carbon emissions, is gaining attention as a core technology for addressing global warming. Green hydrogen is produced through electrolysis, a process that separates hydrogen and oxygen by applying electrical energy to water, requiring low-cost, high-efficiency, high-performance catalysts.
A research team led by Dr. Na Jongbeom and Dr. Kim Jong Min from Korea Institute of Science and Technology’s Center for Extreme Materials Research has developed next-generation water electrolysis catalyst technology. This technology integrates a single-atom “All-in-one” catalyst precisely controlled down to the atomic level with binder-free electrode technology. The study is published in the journal Advanced Energy Materials.
A key feature of this technology is its ability to stably perform both hydrogen evolution and oxygen evolution reactions simultaneously on a single electrode.
Researchers have developed a solar cell system that uses mirrors to concentrate solar energy. In addition to electricity, it produces heat for a plant that will capture carbon from industrial emissions. The solar cells in the large pilot plant are a full 5 meters high and consist of many mirrors that are angled toward the solar cells to concentrate sunlight. They make it possible to collect the sun’s rays into concentrated solar energy, as well as heat that supports a plant designed to capture CO2.
“The system has been tested and validated. It is quite innovative and unique and stands out by storing heat in addition to the electrical current,” says SINTEF research scientist Alfredo Sanchez Garcia.
The energy from the plant will be used to capture carbon from industrial emissions.
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It seems clear that we have given up on trying to stop climate change. It worries me profoundly, not so much because of climate change itself, but because of what it says about our collective ability to make intelligent decisions.
