Chemistry of the p-block

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  • Created by: holly_b
  • Created on: 04-01-17 09:38
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  • p-block
    • Amphoteric Behaviour
      • A substance which can acts as an acid and a base.
      • p-block elements form amphoteric oxides and hydroxides.
        • Lead Oxide
          • As an acid
            • PbO + 2NaOH + H2O --> Na2[Pb(OH)4]
          • As a base
            • PbO + 2HNO3 --> Pb(NO3)2 + H2O
      • Testing for amphoteric metals
        • Solutions with amphoteric metals form precipitates when sodium hydroxide is added
          • On adding excess sodium hydroxide the precipitate will redissolve.
    • Stability
      • The inert pair effect
        • The lower valencies become more stable as the group (3, 4 and 5) is descended.
        • Towards the bottom of the group there is an increasing tendancy for the s2 pair not to be used in the bonding.
        • Ge(IV) is more stable than Ge(II).
    • Octet expansion
      • The octet can be expanded by utilising the d-orbitals
        • Examples
          • PCl5
          • SF6
          • ClO4 -
    • Al2Cl6
      • The electron deficient aluminium uses a lone pair on the chlorine atom to form a coordinate bond.
        • Other molecules can also form coordinate bonds to lose their electron deficiency.
          • These are called donor-acceptor compounds where one molecule donates a lone pair and the other accepts it.
    • Boron Nitride
      • Hexagonal boron nitride vs. graphite
        • Similarities
          • Forms hexagonal sheets.
        • Differences
          • Each boron has a nitrogen atom above and below it but in graphite atoms on adjoining layers are not directly above each other.
          • BN does not have delocalised electrons so it is a good insulator.
          • The B-N bond is polar.
      • Cubic boron nitride
        • Similarities
          • Hard
          • High melting point
        • Uses
          • Wear resistant coating
          • Industrial abrasive
    • Oxidation states in group 4
      • Carbon Monoxide
        • Only stable compound to contain carbon in the +2 oxidation state.
        • Acts as a reducing agent because its easily oxidised to +4.
      • Carbon Dioxide
        • Most stable carbon compound as carbon is in the +4 oxidation state.
        • Acidic oxide which is soluble in water.
          • This leads to the formation of carbonic acid.
      • Lead(II) oxide
        • PbO is the most stable oxide
        • Amphoteric
      • Lead(IV) oxide is the acts as an oxidising agent as it is easily reduced from +4 to +2.
    • Reactions of Cl2
      • Water
        • It forms chloric(I) acid (HOCl) and hydrochloric acid (HCl) in a reversible disproportionation reaction
      • NaOH
        • The equilibrium is shifted to the right
          • The chlorate(I) ion is stable at room temperature.
    • Reactions of lead compounds
      • NaOH
        • White precipitate of Pb(OH)2 is formed
      • NaOH
        • White precipitate of Pb(OH)2 redissolves to form tetrahydroxyplumbate.
      • HCl
        • White precipitate of lead chloride  is formed.
      • KI
        • Yellow precipitate of lead iodide is formed.
    • Reactions of Chlorides
      • Carbon and silicon chlorides are colourless liquids containing individual covalent molecules
      • Stable chlorides = tetrachlorides
      • CCl4 doesn't react with water as there are no available d-orbitals so there is no octet expansion.
      • In silicon there are available d-orbitals so the water molecules can form coordinate bonds.
      • Lead (II) chloride is insoluble in water.
    • Sodium halide solids and concentrated sulfuric acid
      • Chlorine
      • Iodine
      • Bromine

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