Solid oxide fuel cells (SOFCs) are a promising solution to the contemporary problem of the impending global energy crisis. SOFCs show high efficiency, lower emissions, and have low operating costs, making them an ideal power source for a fossil fuel-free society.
In a project commissioned by the New Energy and Industrial Technology Development Organization (NEDO), researchers at Nagoya University in Japan have developed poly(styrenesulfonic acid)-based PEMs with a high density of sulfonic acid groups.
Lithium-ion batteries power our lives.
A team led by professors Zhengyan Wu and Jia Zhang from the Institute of Intelligence at the Chinese Academy of Sciences’ Hefei Institutes of Physical Science worked with professor Dongqing Cai from Donghua University to develop a new primary battery system that can efficiently remove Cd2+ from the environment while generating electricity.
Contact allergies can be quite severe as a result of epoxy resin monomers used in the industry.
Odorous gases are prevalent in places like septic tanks, sewage systems, livestock farms, and waste disposal facilities. They are unpleasant and severely irritate the eyes, nose, and respiratory system.
Although the chemical industry has contributed significantly to the advancement of humanity, concerns over its effects on the environment are mounting.
Scientists at Binghamton University have conducted research in collaboration with the Center for Functional Nanomaterials (CFN) — a U.S. Department of Energy (DOE) Office of Science User Facility at Brookhaven National Laboratory — to get a better understanding of how peroxides on the surface of copper oxide promote the oxidation of hydrogen but prevent the oxidation of carbon monoxide, enabling them to control oxidation reactions.
Molecular switches are chemicals with molecular structures that can change between two or more stable configurations in response to environmental changes. They are of particular interest in the creation of molecular computers, molecular machines, and drug-delivery systems.
To manage atmospheric carbon dioxide and convert the gas into a useful product, Cornell University scientists have dusted off an archaic – now 120 years old – electrochemical equation.
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