Chemistry Textbook
- 1. Matter and MeasurementsToggle Dropdown
- 2. Atoms, Molecules and IonsToggle Dropdown
- 3. Composition of Substances and SolutionsToggle Dropdown
- 4. Stoichiometry of Chemical ReactionsToggle Dropdown
- 5. ThermochemistryToggle Dropdown
- 6. GasesToggle Dropdown
- 7. Chemical Bonding and Molecular Geometry
- 8. Liquids, Solids, and Modern MaterialsToggle Dropdown
- 9. Solutions and Colligative PropertiesToggle Dropdown
- 10. KineticsToggle Dropdown
- 11. Chemical Equilibria and ApplicationsToggle Dropdown
- 12. ThermodynamicsToggle Dropdown
- 13. ElectrochemistryToggle Dropdown
- 14. AppendicesToggle Dropdown
- Appendix A: Periodic Table of Elements
- Appendix B: Essential Mathematics
- Appendix C: Units and Conversion Factors
- Appendix D: Fundamental Physical Constants
- Appendix E: Water Properties
- Appendix F: Composition of Commercial Acids and Bases
- Appendix G: Standard Thermodynamic Properties for Selected Substances
- Appendix H: Ionization Constants of Weak Acids
- Appendix I: Ionization Constants of Weak Bases
- Appendix J: Solubility Products
- Appendix K: Formation Constants for Complex Ions
- Appendix L: Standard Electrode (Half-Cell) Potentials
Summary
Atoms gain or lose electrons to form ions with particularly stable electron configurations. The charges of cations formed by the representative metals may be determined readily because, with few exceptions, the electronic structures of these ions have either a noble gas configuration or a completely filled electron shell. The charges of anions formed by the nonmetals may also be readily determined because these ions form when nonmetal atoms gain enough electrons to fill their valence shells.
Covalent bonds form when electrons are shared between atoms and are attracted by the nuclei of both atoms. In pure covalent bonds, the electrons are shared equally. In polar covalent bonds, the electrons are shared unequally, as one atom exerts a stronger force of attraction on the electrons than the other. The ability of an atom to attract a pair of electrons in a chemical bond is called its electronegativity. The difference in electronegativity between two atoms determines how polar a bond will be. In a diatomic molecule with two identical atoms, there is no difference in electronegativity, so the bond is nonpolar or pure covalent. When the electronegativity difference is very large, as is the case between metals and nonmetals, the bonding is characterized as ionic.
Valence electronic structures can be visualized by drawing Lewis symbols (for atoms and monatomic ions) and Lewis structures (for molecules and polyatomic ions). Lone pairs, unpaired electrons, and single, double, or triple bonds are used to indicate where the valence electrons are located around each atom in a Lewis structure. Most structures—especially those containing second row elements—obey the octet rule, in which every atom (except H) is surrounded by eight electrons. Exceptions to the octet rule occur for odd-electron molecules (free radicals), electron-deficient molecules, and hypervalent molecules.
VSEPR theory predicts the three-dimensional arrangement of atoms in a molecule. It states that valence electrons will assume an electron-pair geometry that minimizes repulsions between areas of high electron density (bonds and/or lone pairs). Molecular structure, which refers only to the placement of atoms in a molecule and not the electrons, is equivalent to electron-pair geometry only when there are no lone electron pairs around the central atom. A dipole moment measures a separation of charge. For one bond, the bond dipole moment is determined by the difference in electronegativity between the two atoms. For a molecule, the overall dipole moment is determined by both the individual bond moments and how these dipoles are arranged in the molecular structure. Polar molecules (those with an appreciable dipole moment) interact with electric fields, whereas nonpolar molecules do not.