9: Coordination Chemistry II- Bonding

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9.1: Evidence for Electronic Structures
9.2: Thermodynamic Data
9.3: Magnetic Susceptibility
The electronic structure of coordination complexes can lead to several different properties that involve different responses to magnetic fields. These properties can vary between related compounds because of differences in electron counts, geometry, or donor strength. As a result, magnetic measurement of these materials can be used as a tool to provide insight into the structure of a coordination complex.
9.4: Crystal Field Theory
9.5: Ligand Field Theory
9.6: Ligand Field Theory - Molecular Orbitals for an Octahedral Complex
Crystal field theory is successful at providing some general insights into the differing energy levels of d orbitals in coordination complexes. That knowledge can help us to understand some of the magnetic properties of these compounds, which are determined by the number of unpaired electrons. It can also help us to understand some of the absorbed wavelengths of light in the UV-visible spectrum, which in some cases depends on the energy difference between different sets of d orbitals.
9.7: Orbital Splitting and Electron Spin
9.8: Ligand Field Stabilization Energy
9.9: Tetrahedral Complexes
Tetrahedral geometry is even more common in chemistry than square planar geometry. Assessing the orbital interactions in tetrahedral geometry is somewhat more complicated, however, and it is common to proceed directly to a group theory approach.
9.10: Ligand Field Theory New Page
9.11: Angular Overlap
The angular overlap model is an approach to quantifying the interaction between metal and ligand orbitals in different geometries, with a focus on the metal d orbitals. Although developed in the 1970's, this approach is still used as a starting point for theoretical calculations using advanced computational chemistry methods available today.
9.12: Sigma Bonding in the Angular Overlap Model
9.13: Pi Acceptors in the Angular Overlap Model
9.14: Pi Donors in the Angular Overlap Model
9.15: The Spectrochemical Series
9.16: The Magnitude of Parameters eσ, eπ and Δ
In the angular overlap model (AOM), the field splitting, \(Δ\), can be shown to result from a combination of the interaction parameters eσ and eπ.
9.17: The Jahn-Teller Effect
Certain metal ions frequently display distortions from ideal geometry, such that the symmetry of the compound is lowered. In tetragonal distortions of octahedral complexes, for example, the metal-ligand bond distances of two axial ligands may be significantly longer than the distances of the equatorial ligands. Alternatively, two of the metal-ligand distances may be compressed compared to others. These distortions are often called Jahn-Teller distortions.

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