oxidation reduction reactions honors
DESCRIPTION
Oxidation and ReductionTRANSCRIPT
OXIDATION-REDUCTION REACTIONS
Settle in, this is going to take a while…
What is redox?
Reaction where there is a transfer of electrons between reactants
Oxidation involves the loss of electrons (OIL) Oxidation number/state of the element
increases Oxidized element is the reducing agent
Reduction involves the gain of electrons (RIG) Oxidation number/state of the element
decreases Reduced element is the oxidizing agent
Example
Complete Reaction:Mg + Zn(NO3)2 Mg(NO3)2 + Zn
Net-ionic Reaction:Mg + Zn2+ Mg2+ + Zn
The magnesium metal was oxidized by the zinc and the zinc was reduced by the magnesium.
Do what?!?!
The oxidation state of the magnesium changed from 0 to +2 Oxidation state increased = oxidation Because magnesium gave its electrons
away, it is the reducing agent The oxidation state of zinc changed from
+2 to 0 Oxidation state decreased = reduction Because zinc took the electrons, it is the
oxidizing agent
How do you know oxidation states? The oxidation number for any pure
element is zero. Group 1 metals form +1 ions, group 2
metals form +2 ions, group 13 metals form +3 ions.
Transition metals can be all kinds of oxidation numbers (ranging from +1 to +7)
Transition metal oxidation states can be determined based on the nonmetal(s) it’s bonded to…
Nonmetal oxidation states
Fluoride is ALWAYS -1, the other halides are usually -1.
Oxide is usually -2, except when it’s in the peroxide ion (-1) or bonded to fluorine (+2)
Hydrogen is +1, unless it is the hydride ion (-1)
Putting it all together
The total charge on a compound is zero, so all oxidation numbers must cancel out.
The total charge of elements in a polyatomic ion must add to the charge on the ion
Practice
What is the oxidation number of each element in the following compounds?
1. Zn(NO3)2
2. H2SO4
3. KMnO4
4. N2O4
5. PCl3
What’s the point?
When an element gains electrons, another element must accept those electrons (Newton’s 3rd law).
If you separate the reaction into half-reactions, you can exploit this electron transfer to generate electricity.
The study of this is electrochemistry, but more on that later…
Half-Reactions?
You can separate a redox reaction into the reduction reaction and the oxidation reaction.
First you have to identify which element is oxidized and which is reduced.
So let’s practice identification first:
Practice
Determine the oxidation states of all elements in the following reactions and then identify which element is oxidized and which is reduced.
N2 + 3H2 2NH3
2MnO2 + Zn + 2H2O 2MnO(OH) + Zn(OH)2
AgNO3 + Cu Cu(NO3)2 + Ag
N2 + 3H2 2NH3
2MnO2 + Zn + 2H2O 2MnO(OH) + Zn(OH)2
AgNO3 + Cu Cu(NO3)2 + Ag
Separating reactions
Once the oxidized and reduced elements have been identified, separate the reactions.
Use net ionic reactions instead of complete reactions
2AgNO3 + Cu Cu(NO3)2 + 2Ag
2Ag+1 + Cu Cu2+ + 2Ag
2Ag+1 + Cu Cu2+ + 2Ag
The silver is reduced, so that is the reduction reaction:
2Ag+1 2Ag The masses are balanced, but the
charges are not, so add the electrons being transferred:
2Ag+1 + 2e- 2Ag Notice that the reduction half reaction
has electrons as reactants
2Ag+1 + Cu Cu2+ + 2Ag
The copper is oxidized, so that is the oxidation reaction:
Cu Cu2+
The masses are balanced, but the charges are not, so add the electrons being transferred:
Cu Cu2+ + 2e-
Notice that the oxidation half reaction has electrons as products