Ferroelectric materials are unusual because they have an electrically positive side and an electrically negative side, and these sides can be switched with an electric field.
A class of material called perovskites, which have special electronic bonding with many applications, could be useful for quantum sensing.
According to a study published in Science, an international team of scientists has discovered a startling element that speeds up the deterioration of lithium-ion batteries, resulting in a consistent loss of charge.
Scientists from the Institute for Integrated Cell-Material Sciences at Kyoto University and the Department of Chemical Engineering at National Taiwan University have developed a phase-transformable membrane that could meet the needs of efficient gas separation.
Scientists from the Chinese Academy of Sciences’ Qingdao Institute of Bioenergy and Bioprocess Technology (QIBEBT) and their associates have created an effective electrocatalyst named Co-N/S-HCS that exhibits exceptional activity and stability in seawater electrolysis, according to a study published in Chem Catalysis on November 13th, 2024.
Pectin has a new use as a photothermal material, according to a study published in Carbohydrate Polymers by Aalto researchers.
Negative-stiffness vibration isolators enhance AFM performance, ensuring stability and precision in nanoscale imaging and measurement applications.
Researchers have revealed a rare-earth-free polymer, Co4(OH)6(SO4)2[enH2], showing a giant magnetocaloric effect, paving the way for sustainable cooling technologies.
Researchers at Rice University have developed a catalyst that uses light instead of heat to drive the reaction in Steam Methane Reforming (SMR), a key process in global hydrogen production. This innovation could make SMR entirely emissions-free, addressing the significant greenhouse gas emissions associated with the chemical process.
With $1.8 million from the National Science Foundation’s second Future of Semiconductor program (FuSe2), the University of Kansas and the University of Houston will collaborate to develop atomically tunable memory resistors, or "memristors," for brain-inspired advanced computing, while also preparing the workforce for the nation’s semiconductor industry.
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