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12: Chemical Bonding

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    323334
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    How do atoms make compounds? Typically they join together in such a way that they lose their identities as elements and adopt a new identity as a compound. These joins are called chemical bonds. But how do atoms join together? Ultimately, it all comes down to electrons. Before we discuss how electrons interact, we need to introduce a tool to simply illustrate electrons in an atom.

    • 12.1: Prelude to Chemical Bonds
      Diamond is the hardest natural material known on Earth. Yet diamond is just pure carbon. What is special about this element that makes diamond so hard? Bonds. Chemical bonds.
    • 12.2: Representing Valence Electrons with Dots
      The Lewis Structure of a molecule shows how the valence electrons are arranged among the atoms of the molecule. Lewis electron dot diagrams use dots to represent valence electrons around an atomic symbol. Lewis electron dot diagrams for ions have less (for cations) or more (for anions) dots than the corresponding atom. From experimentation, chemists have learned that when a stable compound forms, the atoms usually have a noble gas electron configuration—or eight valence electrons.
    • 12.3: Lewis Structures of Ionic Compounds- Electrons Transferred
      The tendency to form species that have eight electrons in the valence shell is called the octet rule. The attraction of oppositely charged ions caused by electron transfer is called an ionic bond. The strength of ionic bonding depends on the magnitude of the charges and the sizes of the ions.
    • 12.4: Covalent Lewis Structures- Electrons Shared
      Covalent bonds are formed when atoms share electrons. Lewis electron dot diagrams can be drawn to illustrate covalent bond formation. Double bonds or triple bonds between atoms may be necessary to properly illustrate the bonding in some molecules.
    • 12.5: Writing Lewis Structures for Covalent Compounds
      Lewis dot symbols provide a simple rationalization of why elements form compounds with the observed stoichiometries. A plot of the overall energy of a covalent bond as a function of internuclear distance is identical to a plot of an ionic pair because both result from attractive and repulsive forces between charged entities. In Lewis electron structures, we encounter bonding pairs, which are shared by two atoms, and lone pairs, which are not shared between atoms.
    • 12.6: Violations of the Octet Rule
      There are three violations to the octet rule: odd-electron molecules, electron-deficient molecules, and expanded valence shell molecules.
    • 12.7: Resonance - Equivalent Lewis Structures for the Same Molecule
      Resonance structures are averages of different Lewis structure possibilities. Bond lengths are intermediate between covalent bonds and covalent double bonds.
    • 12.8: Predicting the Shapes of Molecules
      The approximate shape of a molecule can be predicted from the number of electron groups and the number of surrounding atoms.
    • 12.9: Electronegativity and Polarity - Why Oil and Water Don’t Mix
      Covalent bonds can be nonpolar or polar, depending on the electronegativities of the atoms involved. Covalent bonds can be broken if energy is added to a molecule. The formation of covalent bonds is accompanied by energy given off. Covalent bond energies can be used to estimate the enthalpy changes of chemical reactions.
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