Inorganic Chemistry
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Chemistry of metals, coordination compounds, crystal field theory, and main group chemistry.
Coordination Compounds and Ligands
Metal complexes and coordination number
Crystal Field Theory
How ligands split d-orbital energy levels
Organometallic Chemistry Fundamentals
Compounds with metal-carbon bonds
Bioinorganic Chemistry: Metals in Biology
Iron in hemoglobin, zinc in enzymes, and more
Solid State Chemistry and Crystallography
Crystal systems, defects, and X-ray diffraction
Main Group Chemistry: s-Block and p-Block
Chemistry of representative elements
Industrial Inorganic Chemistry
Haber process, Contact process, and metal extraction
Symmetry and Group Theory in Chemistry
Point groups and symmetry operations for molecules
Inorganic Reaction Mechanisms
Ligand substitution and electron transfer reactions
Rare Earth Elements and Their Applications
Critical materials for technology and industry
Transition Metal Catalysis in Industry
From Haber-Bosch to cross-coupling — metals that drive modern chemistry
Supramolecular Chemistry: Beyond the Covalent Bond
Host-guest chemistry, self-assembly, and molecular machines
Chemistry of Ceramics and Glass
Silicon-oxygen networks, glazes, and high-tech ceramics
Lanthanide Chemistry and Modern Applications
Rare earths in magnets, lasers, and green energy
Actinide Chemistry: From Nuclear Fuel to Waste
Uranium, plutonium, and the chemistry of nuclear energy