2: Bonding Theory Overview

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2.1: Covalent- Lewis Octet
The bonding between atoms in a molecule can be topically modeled though Lewis electron dot diagrams. Creating Lewis diagrams is rather simple and requires only a few steps and some accounting of the valence electrons on each atom. Valence electrons are represented as dots. When two electrons are paired (lone pairs), they are represented by two adjacent dots located on an atom, and when two paired electrons are shared between atoms (bonds), they are shown as lines.
2.2: Covalent- Molecular Orbital Theory
In the previous sections, we saw how to predict the approximate geometry around an atom using VSEPR theory, and we learned that lone pairs of electrons slightly distort bond angles from the "parent" geometry. This page discusses the effect of multiple (double and triple) bonds between bonded atoms.
2.3: Metallic- Sea of Electrons and the van Arkel-Ketelaar Triangle
This page discusses the "sea of electrons" model introduced by Paul Drüde in the early 1900s, explaining metallic bonding and its properties like high melting points and conductivity. It also explores factors affecting bond strength and the van Arkel-Ketelaar Triangle, which visualizes the continuum of ionic, metallic, and covalent bonds among main group elements.
2.4: Structures of Metals and Ionic Compounds
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.
2.5: Ionic- Charge and Size Determine Ionic Bonding
The energetics of an ionic solid can be approximated reasonably well by considering the attraction and repulsion between ions in the crystal

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