Transition metals exchange electrons with supporting ligands to form complexes that facilitate reaction catalysis in several industries, like pharmaceutical production. Both the metal center and the ...

Transition metal chemistry is a vast and dynamic field that centres on the distinctive properties of elements in groups 3–12. These metals, characterised by partially filled d orbitals, exhibit a ...

Valence tautomerism (VT) in transition metal complexes is a fascinating phenomenon in which reversible intramolecular electron transfer between the metal centre and a redox‐active ligand results in ...

Transition metals play a crucial role in various industries, such as pharmaceutical production, by exchanging electrons with supporting ligands to create complexes that facilitate catalytic reactions.

Skeletons I-V containing three or four coplanar M–C σ bonds are shown on the left. The two skeletons with five coplanar M–C σ bonds are placed on the right. Art by Dafa Chen. This study is led by Dr.

Transition metal fluorides are widely regarded as promising cathode materials because of their high theoretical voltages and ...

Antibiotic resistance is steadily eroding one of modern medicine’s most essential tools. Each year, more than a million people lose their lives to infections that were once easily treatable, a ...

Speeding up chemical reactions is key to improving industrial processes or mitigating unwanted or harmful waste. Realizing these improvements requires that chemists design around documented reaction ...

Transition metals form catalytic complexes that can speed up various chemical processes, especially in the production of pharmaceuticals as well as various pigments, dyes, and laboratory reagents like ...