chapter 6 - shapes of molecules, and intermolecular forces

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    • tetrahedral shape

      4 bonded pairs
      109.5 bond angle
    • pyramidal
      3 bonding pairs
      1 lone pair
      107 bond angle
    • non-linear
      2 bonding pairs
      2 lone pairs
      104.5
    • the bond angle is reduced by 2.5 for each lone pair
    • CO2 has a linear shape
    • octahedral
      6 bonding pairs
      90 bond angle
    • ammonium has a tetrahydral shape
    • nitrate has a trigonal planar shape
    • trigonal planar
      3 bonding pairs
      120 bond angle
    • sulfate ions have a tetrahyral shape
    • the attraction of a bonded atom for the pair of electrons in a covalent bond is called electronegativity
    • electronegativity trends
      across the periodic table - electronegativity increases
      down the periodic table - electronegativity decreases
    • Why does electronegativity increase across the periodic table?
      • nuclear charge increases
      • the atomic radius decreases
    • if the electronegativity difference in a molecule is 0, the bond is covalent
      if it is 0 to 1.8, the bond is polar covalent
      if it is larger than 1.8, the bond is ionic
    • a pure covalent bond is where the bonded atoms come from the same element
    • a polar covalent bond is when the bonded atoms have different electronegativity values
    • if a molecule is symmetrical, the dipoles cancel each other out, and the molecule is not polar
    • three main types of intermolecular forces
      • induced dipole-dipole interactions (london)
      • permanent dipole-dipole interactions
      • hydrogen bonding
    • london forces are the weakest
      permanent dipole-dipole interactions are stronger
      hydrogen bonds are strongest of intermolecular
    • how a london bond is formed
      • movement of electrons produces a changing dipole in a molecule
      • at any instant, and instantaneous dipole will exist, but its position is constantly shifting
      • the instantaneous dipole induces a dipole on a neighbouring molecule
      • the induced dipole induces further dipoles on neighbouring molecules, which then attract one another
    • the strength of induced dipole-dipole interactions
      the more electrons in a molecule:
      • the larger the instantaneous and induced dipole
      • the greater the induced dipole-dipole interactions
      • the stronger the attractive forces between molecules
    • permanent dipole-dipole interactions act between the permanent dipoles in different polar molecules
    • in solid state, sample molecules form a simple molecular lattice
    • properties of simple molecular substances
      • low melting and boiling points (weak intermolecular forces)
      • non polar substances soluble in non-polar solvents, they tend to be insoluble in polar solvents
      • no mobile charged particles, so they do not conduct electricity
    • non-polar simple molecular compound dissolving in non-polar solvent
      intermolecular forces form between the molecules and the solvent
      these interactions weaken the intermolecular forces in the simple molecular lattice, they break and the compound dissolves
    • solubility of polar simple molecular substances
      depends on the strength of the dipole, and can be hard to predict
    • hydrogen bonds can from between an electronegative atom, with a lone pair of electrons (e.g. oxygen, nitrogen or fluorine) and hydrogen
    • properties of water
      • ice less dense than liquid (hydrogen bonds hold water molecules further apart in ice)
      • water has a relatively high melting and boiling point, because of the strong hydrogen bonds between molecules
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