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In a reduction-oxidation reaction, one species gains electrons while the other loses them. We can divide up the overall redox reactions into two half-reactions, one for the oxidation and one for the reduction. Balancing these half reactions is a bit tricky, but necessary to properly balance redox reactions.

One good way to proceed is the following 5 step method. First, identify what's being oxidized or reduced: it's the thing that's changing it's oxidation number.

  1. Balance the atom being oxidized or reduced.
  2. Balance the oxidation number by adding electrons. Electrons have a -1 oxidation number.
  3. Balance the charge by adding H+ if the reaction is done in an acidic solution or by adding OH- ions if in a base.
  4. Balance the hydrogens by adding water molecules
  5. Check to see if the oxygen atoms are balanced: if they are, you correctly balanced the 1/2 reaction.

An example or two hopefully will make this clearer. Let's balance the following reaction in acid:

Cu+2(s) -> Cu(s)
It should be fairly obvious that the copper is being reduced. We've therefore identified the species being reduced, so
  1. Balance the atom being reduced: 1 copper on each side, already balanced: Cu+2(s) -> Cu(s)
  2. Balance the oxidation number: Cu+2 is +2, Cu(s) is 0. Since electrons are -1, adding two to the left gives both sides 0:Cu+2(s) + 2e- -> Cu(s)
  3. Balance charge: 0 on both sides, already balanced: Cu+2(s) + 2e- -> Cu(s)
  4. Balance hydrogens: 0 on both sides, already balanced: Cu+2(s) + 2e- -> Cu(s)
  5. Check oxygens: 0 on both sides, already balanced: Cu+2(s) + 2e- -> Cu(s)
We're done: the balanced 1/2 reaction is Cu+2(s) + 2e- -> Cu(s)

A more complex example should be helpful. Let's balance the following reaction in acid

MnO4-(aq) -> Mn+2(aq)
The manganese is the species being reduced. (Why?) Now let's follow our steps
  1. Balance the atom being reduced: 1 Mn on each side, already balanced: MnO4-(aq) -> Mn+2(aq)
  2. Balance the oxidation number: the Mn in the MnO4- has an oxidation number of +7, the Mn+2 has an oxidation number of +2. (Remember how to compute oxidation number?) Add 5 electrons to the left side: MnO4-(aq) + 5e- -> Mn+2(aq)
  3. Balance charge: Total charge on the left is -6, on the right is +2. We're in acid, so add 8 H+ ions to the left to get +2 on each side: MnO4-(aq) + 5e- +8H+(aq) -> Mn+2
  4. Balance the hydrogens by adding water: 8 H on the left, none on the right, so add four water to the right: MnO4-(aq) + 5e- +8H+(aq) -> Mn+2(aq) + 4H2O(l)
  5. Check the number of oxygens: there are four on both sides, so we're done
The balanced 1/2 reaction is MnO4-(aq) + 5e- +8H+(aq) -> Mn+2(aq) + 4H2O(l)

Example: Balance the following 1/2 reaction in acid

NO3-(g) -> NO(g)

Solution. The nitrogen is being reduced.

  1. >Balance the atom being reduced: 1 N on each side, already balanced: NO3-(g) -> NO(g)
  2. Balance the oxidation number: The nitrogen in the NO3- has an oxidation number of +5 and the nitrogen in the NO has an oxidation number of +2. Add 3 electrons to the left: NO3-(g) + 3e- -> NO(g)
  3. Balance the charge: the charge is -4 on the left, 0 on the right. We're in acid, so add 4H+ to the left: NO3-(g) + 3e- + 4H+(aq) -> NO(g)
  4. Balance the hydrogens: 4 on the left, none on the right, add 2 water to the right: NO3-(g) + 3e- + 4H+(aq) -> NO(g) + 2H2O(l)
  5. Check oxygens: three on each side, so we're done
The balanced 1/2 reaction is NO3-(g) + 3e- + 4H+(aq) -> NO(g) + 2H2O(l)


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