In 1825 Michael Faraday isolated a sweet-smelling chemical that he dubbed bi-carburet of hydrogen. That molecule, better ...

A groundbreaking new method developed at the University of Osaka calculates the entropy of liquids using a non-empirical approach, requiring only the atomic species as input. The paper is published in ...

Once thought unlikely, this new finding in coordination chemistry could lead to promising advances in catalysis and materials science. For more than 100 years, the widely accepted 18-electron rule has ...

High-resolution cryo-electron microscopy makes it possible to study complex enzymatic processes in detail. With this method, a research team of the University of Potsdam and Humboldt-Universität ...

Prof. Hening Lin brings expertise in enzymes to UChicago, bridging scientists, engineers and doctors to translate research to ...

Join us in this thrilling video where we conduct an astonishing experiment with 10,000 matches! Watch as one match ignites a mesmerizing chain reaction, creating a stunning visual spectacle. This ...

Microwave-assisted catalytic reactions are considered energy-efficient and have attracted attention in various chemical ...

Recent research has employed chemical reaction networks (CRNs), which harness biochemical processes for computations that translate interactions involving biochemical species into graphical form.

The executive order pushing a new “gold standard” of science is profoundly troublesome, as Leigh Krietsch Boerner describes ...

These are temporal realms that set the stage for many chemistry antics: things like electrons shifting between excited higher ...

An attosecond—or 0.000000000000000001 second—is no time at all for a person. That is not so for electrons, atoms and molecules, and laser-wielding scientists are revealing the action ...

Scientists at ETH Zurich have developed a powerful method to look deep inside single-atom catalysts—materials where every ...