By converting air into fertilizer, scientists at Stanford University and the Department of Energy’s Oak Ridge National Laboratory are reducing carbon emissions.
Stable and eco-friendly organic solar cells can be made from lignin, one of the most abundant organic compounds found in nature. It has now been demonstrated by researchers at Linköping University and the Royal Institute of Technology (KTH) that organic solar cells may be further enhanced by using untreated kraft lignin.
The fight to replace carbon-based energy sources with low- or no-carbon alternatives is a constant one. The solution might lie in the process of splitting water.
Scientist Javier Grajeda of Eastman and chemist Alex Miller of the University of North Carolina-Chapel Hill are spearheading a cooperative academic-industry team to find more environmentally friendly ways to develop the fundamental building blocks of the chemical industry.
The demand for battery power is surging as we buy more devices, gas prices climb higher and countries transition to alternative energy sources. A recent study published by Statista projects that global demand for batteries will increase tenfold by 2030.
Hydrogen is a highly combustible gas that, if produced in an environmentally friendly manner, can help the world meet its clean energy goals.
Vanadium redox flow batteries, which can store a significant amount of energy and are used by a variety of industries, including electric power utilities, have a successful method for reducing charge capacity loss described in an article published by researchers at the Center for Development of Functional Materials (PDFF) in Brazil. The Chemical Engineering Journal published the article.
A rechargeable hydrogen-chlorine battery developed by CAS researchers operates from -70 °C to 40 °C, enhancing performance and stability in extreme conditions.
It is with great pride that De Dietrich Process Systems presents its latest piece of equipment in its Tech Lab: the Pan Dryer.
Tokyo Tech scientists showcased that donor doping within a mother material containing disordered intrinsic oxygen vacancies, as opposed to the commonly employed acceptor doping in vacancy-free materials, significantly amplifies the conductivity and durability of perovskite-type proton conductors within the temperature range of 250–400 ?.
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