3: Bonding and Intermolecular Forces

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3.0: Introduction
From Lab Bench to Body Armor: The Story of Kevlar
3.1: Chemical Bonds
Bonds form because the compound together is more stable than the elements apart. There are three idealized types of bonding: covalent bonding, ionic bonding, and metallic bonding.
3.2: Ionic Bonding
Atoms tend to gain or lose electrons to form ions, anions and cations, with particularly stable electron configurations. An ionic bond is the electrostatic force of attraction between these oppositely charged cations and anions. Due to the attraction between oppositely charged ions, the ionic compound has a lower energy than the ions apart.
3.3: Covalent Bonding
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.
3.4: Lewis Structures
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.
3.5: Molecular Structure and Polarity
VSEPR theory is a model that predicts the 3-D structure of simple molecules by assuming that electrons will assume a geometry that minimizes repulsions between electron groups (bonds and/or lone pairs). A dipole moment measures a separation of charge. 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.
3.6: Intermolecular Forces
Intermolecular forces are electrostatic attractive forces between molecules and they influence the properties of matter, including the physical state. The three types of intermolecular forces are dispersion forces, which are present between all atoms and molecules, dipole-dipole attractions, which occur between polar molecules, and hydrogen bonds, a special type of dipole-dipole attraction that occurs when hydrogen is bonded to one of the three most electronegative elements: F, O, or N.
3.E: Bonding and Intermolecular Forces (Exercises)
Working through the problems at the end of each chapter is an essential part of learning chemistry. These questions help you check your understanding of key concepts, practice applying them to new situations, and develop problem-solving skills. They also provide a useful way to assess your readiness before moving on to the next topic or preparing for assessments.

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