Hybrid Orbitals: Theory and Applications

Related lectures (32)

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Explores molecular geometry, hybridization, dipole moments, and intermolecular forces in chemical compounds.

Covers the fundamentals of quantum chemistry, focusing on molecular orbital theory and conservation of orbital equivalence.

Explores the symmetry analysis of a deuterated metal hydride complex and its molecular orbitals.

Explores atomic orbitals, hybridization, bond formation, and electron delocalization in covalent bonds.

Explores chemical bonding in crystal lattices and ionic solids, including properties of ionic compounds and molecular orbitals.

Explores the transition from atomic to molecular orbitals, covering quantum systems, approximations, valence electrons, and covalent bonds.

Discusses molecular orbitals in π-conjugated systems, focusing on their properties and electronic interactions.

Explores molecular orbitals in conjugated systems, discussing bond lengths, energy barriers, Hückel theory, and aromaticity.

Explores crystal lattices, ionic compounds, properties of ionic compounds, and covalent bonds.

Explores the Schrödinger Equation, quantum numbers, atomic orbitals, and molecular orbital theory in quantum mechanics.