6: Ionic Compounds

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6.1: Unit Cells
Solid state structures can be visualized as spheres packed into a box. There are two closest packed arrangements which fill the largest possible space in the box, as well as arrangements where the spheres are packed less densely. The structure of a larger crystal can be represented by a unit cell, the smallest repeating unit.
6.2: Ionic Radii and Radius Ratios
6.3: Lattice Energy
The energetics of an ionic solid can be approximated reasonably well by considering the attraction and repulsion between ions in the crystal
6.4: Born-Haber Cycles
Lattice enthalpy is a measure of the strength of the forces between the ions in an ionic solid. The greater the lattice enthalpy, the stronger the forces. Those forces are only completely broken when the ions are present as gaseous ions, scattered so far apart that there is negligible attraction between them. You can show this on a simple enthalpy diagram.
6.5: Ionic Lattices - Examples
6.6: Lattice Energy and Solubility
Lattice energies can also help predict compound solubilities. For a solid to be soluble, the energy required to break the lattice must be offset by the solvation of the ions or molecules in solvent
6.7: Solubility Equilibria
The solubility product (Ksp) is used to calculate equilibrium concentrations of the ions in solution, whereas the ion product (Q) describes concentrations that are not necessarily at equilibrium. The equilibrium constant for a dissolution reaction, called the solubility product (Ksp), is a measure of the solubility of a compound. Whereas solubility is usually expressed in terms of mass of solute per 100 mL of solvent, Ksp is defined in terms of the molar concentrations of the component ions.

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