Chipmaking has become one of the world’s most critical technologies in the last two decades. The main driver of this explosive growth has been the continuous scaling of silicon technology (widely known as the Moore’s Law).
Much smaller and more accurate sensors are needed to address longstanding problems in biomedical research, such as tracking the distribution of drugs throughout the body and monitoring brain chemistry.
Without the use of solvents, researchers from the MESA+ Institute at the University of Twente, Riga Technical University, and the Department of Chemical Engineering at the Vrije Universiteit Brussel have managed to arrange extremely small particles (10 µm to 500 nm, 10 to 100 times thinner than a human hair) in a thin layer
The size restriction of conventional ferroelectric effects has been broken by recent research, which has confirmed through theoretical models and experimental data that solid-state ferroelectric effects can be exhibited by structures with as little as 5,000 atoms.
The world's thinnest, strongest, and most flexible material, graphene, could be inhaled under carefully regulated conditions without having any negative short-term consequences on lung or cardiovascular function, according to a study.
Researchers from Utrecht University, Harvard Department of Chemistry & Chemical Biology, and Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) have reported on a previously obscure method to enhance the selectivity of catalytic reactions.
To engineer produce that lasts longer and is free of bacteria, chemical engineering professor Dr Mustafa Akbulut and professor of horticultural science Luis Cisneros-Zevallos have teamed up.
Researchers from the University of Waterloo have developed a new hydrogel made from cellulose nanocrystals derived from wood pulp, which mimics human tissue properties and could be used to heal damaged heart tissue and improve cancer treatments through personalized therapies using tumor organoids.
Tokyo Metropolitan University scientists have developed a novel method for creating “nanoscrolls” out of atomically thin sheets of atoms.
Researchers at Cornell University identified an uncommon event in a metal-insulating material, offering vital insights for the creation of materials with novel features through rapid transition between states of matter.
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