Bond polarity

(noun)

A covalent bond is polar if one atom is more electronegative than its bonding partner, resulting in a net dipole moment between the two atoms.

Related Terms

  • dipole
  • polarity
  • dipole moment
  • Molecular polarity

Examples of Bond polarity in the following topics:

  • Bond Polarity

    • Bond polarity exists when two bonded atoms unequally share electrons, resulting in a negative and a positive end.
    • Bonds can fall between one of two extremes, from completely nonpolar to completely polar.
    • The terms "polar" and "nonpolar" usually refer to covalent bonds.
    • To determine the polarity of a covalent bond using numerical means, find the difference between the electronegativity of the atoms; if the result is between 0.4 and 1.7, then, generally, the bond is polar covalent.
    • The hydrogen fluoride (HF) molecule is polar by virtue of polar covalent bonds; in the covalent bond, electrons are displaced toward the more electronegative fluorine atom.
  • Bond Polarity

    • Molecular polarity is dependent on the presence of polar covalent bonds and the molecule's three-dimensional structure.
    • Bond polarity: when atoms from different elements are covalently bonded, the shared pair of electrons will be attracted more strongly to the atom with the higher electronegativity.
    • Such bonds are said to be 'polar' and possess partial ionic character.
    • In molecules containing more than one polar bond, the molecular dipole moment is just the vector addition of the individual bond dipole moments.
    • Apply knowledge of bond polarity and molecular geometry to identify the dipole moment of molecules
  • Types of Bonds

    • Pure ionic bonding cannot exist: all ionic compounds have some degree of covalent bonding.
    • The larger the difference in electronegativity between the two atoms involved in the bond, the more ionic (polar) the bond is.
    • Bonds with partially ionic and partially covalent character are called polar covalent bonds.
    • This difference in charge is called a dipole, and when the covalent bond results in this difference in charge, the bond is called a polar covalent bond.
    • Similarly, the higher the difference in electronegativity, the more unequal the sharing of electrons is between the nuclei, and the higher the polarity of the bond.
  • Charge Distribution in Molecules

    • Such a covalent bond is polar, and will have a dipole (one end is positive and the other end negative).
    • The degree of polarity and the magnitude of the bond dipole will be proportional to the difference in electronegativity of the bonded atoms.
    • Thus a O–H bond is more polar than a C–H bond, with the hydrogen atom of the former being more positive than the hydrogen bonded to carbon.
    • Methane is essentially non-acidic, since the C–H bond is nearly non-polar.
    • As noted above, the O–H bond of water is polar, and it is at least 25 powers of ten more acidic than methane.
  • Water’s Polarity

    • Water's polarity is responsible for many of its properties including its attractiveness to other molecules.
    • One of water's important properties is that it is composed of polar molecules.
    • The two hydrogen atoms and one oxygen atom within water molecules (H2O) form polar covalent bonds.
    • As a result of water's polarity, each water molecule attracts other water molecules because of the opposite charges between them, forming hydrogen bonds.
    • This interactive shows the interaction of the hydrogen bonds among water molecules.
  • Ionic vs Covalent Bond Character

    • The bond formed between any two atoms is not a purely ionic bond.
    • In the conventional presentation, bonds are designated as ionic when the ionic aspect is greater than the covalent aspect of the bond.
    • Bonds that fall in between the two extremes, having both ionic and covalent character, are classified as polar covalent bonds.
    • This bond is considered to have characteristics of both covalent and ionic bonds.
    • Discuss the idea that, in nature, bonds exhibit characteristics of both ionic and covalent bonds
  • Covalent Bonds

    • Covalent bonding interactions include sigma-bonding (σ) and pi-bonding (π).
    • Double bonds occur when four electrons are shared between the two atoms and consist of one sigma bond and one pi bond.
    • For atoms with equal electronegativity, the bond between them will be a non-polar covalent interaction.
    • In non-polar covalent bonds, the electrons are equally shared between the two atoms.
    • For atoms with differing electronegativity, the bond will be a polar covalent interaction, where the electrons will not be shared equally.
  • Ion-Dipole Force

    • The ion-dipole force is an intermolecular attraction between an ion and a polar molecule.
    • However, ion-dipole forces involve ions instead of solely polar molecules.
    • Ion-dipole bonding is also stronger than hydrogen bonding.
    • Ion-dipole forces are generated between polar water molecules and a sodium ion.
    • These intermolecular ion-dipole forces are much weaker than covalent or ionic bonds.
  • Polarization

    • The concept of polarity is very broad and can be applied to molecules, light, and electric fields.
    • This constant is the degree of their polarizability (the extent to which they become polarized).
    • On the molecular level, polarization can occur with both dipoles and ions.
    • In polar bonds, electrons are more attracted to one nucleus than to the other.
    • For example, table salt (NaCl) is formed from Na+ and Cl- ions that are not formally bound to one another through a chemical bond, but interact very strongly due to their opposite charges.
  • Water’s Solvent Properties

    • Water's polarity makes it an excellent solvent for other polar molecules and ions.
    • A polar molecule with partially-positive and negative charges, it readily dissolves ions and polar molecules.
    • The charges associated with these molecules form hydrogen bonds with water, surrounding the particle with water molecules.
    • When ionic compounds are added to water, individual ions interact with the polar regions of the water molecules during the dissociation process, disrupting their ionic bonds.
    • Since many biomolecules are either polar or charged, water readily dissolves these hydrophilic compounds.
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