Combining two techniques, analytical chemists at the Department of Energy's Oak Ridge National Laboratory became the first to detect fluorine and different isotopes of uranium in a single particle at the same time.
Lithium-ion batteries have long dominated the market as the go-to power source for electric vehicles. They are also increasingly being considered for storage of renewable energy to be used on the electric grid. However, with the rapid expansion of this market, supply shortages of lithium are projected within the next five to 10 years.
Scientists are pioneering a new approach to designing electrolytes for more energy-efficient and less carbon-intensive electrochemical processes. They hope to improve electrolyte performance in applications such as iron production for steel.
A research team at the University of Xiamen has created a machine learning potential for Pt-water interfaces.
In a study published in the Chinese Journal of Catalysis, a research team led by Prof. Gang Wu (University at Buffalo, The State University of New York, United States) and Dr. Dong Tian (University of Jinan, China) developed a self-supported CNTs-Ni-Ni(OH)2 film catalyst with a 3D structure for activated HER.
Scientists at Max Planck have created an environmentally benign method that combines metal extraction, alloying, and processing into a single phase.
In a recent study published in the journal eScience, researchers from Northeastern University presented a new method for building a KF/Zn-rich hybrid interface layer on potassium metal.
While the lithium-ion battery could help save the planet, it is in some ways like any other battery: it degrades with time and operation, taking a toll on its lifespan.
According to a study published in Carbon Future on September 5th, 2024, chemists at Yale University and their colleagues have developed an electrochemical catalyst and membrane that provides an efficient and sustainable method for treating water contaminated with trichloroethylene (TCE), a common and persistent environmental pollutant.
In their quest for a more power-efficient future, researchers at Tohoku University have effectively boosted the capacity, lifespan durability, and cost-effectiveness of a capacitor, according to a study published in ACS Applied Materials & Interfaces.
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