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Category: sustainability

Lithium-ion batteries have been a staple in device manufacturing for years, but the liquid electrolytes they rely on to function are quite unstable, leading to fire hazards and safety concerns. Now, researchers at Penn State are pursuing a reliable alternative energy storage solution for use in laptops, phones and electric vehicles: solid-state electrolytes (SSEs).

According to Hongtao Sun, assistant professor of industrial and manufacturing engineering, solid-state batteries—which use SSEs instead of liquid electrolytes—are a leading alternative to traditional . He explained that although there are key differences, the batteries operate similarly at a fundamental level.

“Rechargeable batteries contain two internal electrodes: an anode on one side and a cathode on the other,” Sun said. “Electrolytes serve as a bridge between these two electrodes, providing fast transport for conductivity. Lithium-ion batteries use liquid electrolytes, while solid-state batteries use SSEs.”

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Japan has taken a significant step forward in renewable energy with the successful deployment of its first megawatt-scale tidal turbine, the AR1100. Installed in the Naru Strait, this 1.1 MW tidal turbine represents a major breakthrough in marine energy technology. As Japan moves towards a sustainable, fossil-fuel-free future, tidal energy is poised to play a crucial role in the country’s energy transition.

This latest achievement builds upon the success of the AR500 pilot project, which demonstrated the viability of tidal energy with a 97% availability rate. With the AR1100 now operational, Japan has entered the global race to harness ocean power on a large scale.

This article will explore how tidal energy works, the advantages of this technology, Japan’s commitment to renewable energy, and the impact of the AR1100 project on the future of clean power generation.

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A study conducted by CNRS researchers describes a new method of recycling silicone waste (caulk, sealants, gels, adhesives, cosmetics, etc.). It has the potential to significantly reduce the sector’s environmental impacts.

This is the first universal recycling process that brings any type of used silicone material back to an earlier state in its where each molecule has only one silicon atom. And there is no need for the currently used to design new silicones. Moreover, since it is chemical and not mechanical recycling, the reuse of the material can be carried out infinitely.

The associated study is published in Science.

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The Tesla robotaxi service, as stated, would be a significant leap in capability from what is currently available.

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A new study in Science shows that the incorporation of a synthetic molecule into the design enhances the energy efficiency and longevity of perovskite solar cells. The benefits of the molecule, known as CPMAC, were found through an international collaboration that included King Abdullah University of Science and Technology (KAUST).

CPMAC is an abbreviation for an ionic salt synthesized from buckminsterfullerene, a black solid made of known as C₆₀. Perovskite are typically made with C₆₀, which has contributed to record energy efficiency. While preferred, C₆₀ also limits the performance and stability of the solar cells, leading scientists to explore alternative materials.

“For over a decade, C₆₀ has been an integral component in the development of perovskite solar cells. However, at the perovskite/C₆₀ interface lead to mechanical degradation that compromises long-term solar cell stability. To address this limitation, we designed a C₆₀-derived ionic salt, CPMAC, to significantly enhance the stability of the perovskite solar cells,” explained Professor Osman Bakr, Executive Faculty of the KAUST Center of Excellence for Renewable Energy and Sustainable Technologies (CREST), who led the KAUST contributions to the research.

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Using spill-treating agents to clean up oil spills does not significantly hinder naturally occurring oil biodegradation, according to a new study. The research, published in Applied and Environmental Microbiology, provides information that will be useful in future oil spills.

Biodegradation is an incredibly important natural process when it comes to . A significant portion of the oil can be permanently removed from the contaminated area through . On-scene coordinators and other first responders must weigh the benefits against potential risks of any response action, such as using spill-treating agents. Emergency response actions to vary widely depending on the scale of an oil spill, location and environmental conditions.

Different treating agents serve different functions. Oil dispersants break the oil into smaller droplets. Surface washing agents lift stranded oil from solid substrates. Chemical herders corral oil into a thicker slick to ease mechanical removal and can also enhance burning efficiency.

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Catalytic conversion of waste CO2 into value-added fuels and chemicals offers unprecedented opportunities for both environmental protection and economic development. Electrocatalytic CO2 reduction reaction (CO2RR) has garnered significant attention for its ability to efficiently convert CO2 into clean chemical energy under mild conditions. However, the relatively high energy barrier for *COOH intermediate formation often becomes the determining step in CO2RR, significantly limiting reaction efficiency.

Inspired by , a team led by Prof. Jiang Hai-Long and Prof. Jiao Long from the University of Science and Technology of China (USTC) of the Chinese Academy of Sciences (CAS) developed a novel strategy to stabilize *COOH intermediate and enhance electrochemical CO2 reduction by constructing and modulating the hydrogen-bonding microenvironment around catalytic sites. Their work is published in the Proceedings of the National Academy of Sciences.

In this work, the team co-grafted catalytically active Co(salen) units and proximal pyridyl-substituted alkyl (X-PyCn) onto Hf-based MOF nanosheets (MOFNs) via a post decoration route, affording Co&X-PyCn/MOFNs (X = o, m or p representing the ortho-, meta-, or para-position of pyridine N relative to alkyl chain; n = 1 or 3 representing the carbon atom number of alkyl chains) materials.

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University of Queensland researchers have set a world record for solar cell efficiency with eco-friendly perovskite technology. A team led by Professor Lianzhou Wang has unveiled a tin halide perovskite (THP) solar cell capable of converting sunlight to electricity at a certified record efficiency of 16.65%. The research is published in the journal Nature Nanotechnology.

Working across UQ’s Australian Institute for Bioengineering and Nanotechnology and the School of Chemical Engineering, Professor Wang said the certified reading achieved by his lab was nearly one percentage point higher than the previous best for THP solar cells.

“It might not seem like much, but this is a giant leap in a field that is renowned for delicate and incremental progress,” Professor Wang said.

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