Cell Potential Under Nonstandard Conditions (College Board AP® Chemistry)
Study Guide
Written by: Philippa Platt
Reviewed by: Stewart Hird
Cell Potential & Equilibrium
Deviations from standard conditions and cell potential
Equilibrium arguments, such as Le Châtelier’s principle, do not apply to electrochemical systems because these systems are not in equilibrium
For a standard cell where the concentrations are the same, the reaction quotient, Q, will be equal to 1
Reaction quotient, Q =
Since we know that the standard cell potential is calculated at 1 M and 1 atm, we know that the value for Q (the reaction quotient) would have to be 1
As a cell reaches equilibrium, the reaction quotient reaches the equilibrium constant, K, (Q = K ) and the magnitude of the cell potential decreases to zero
The cell is not creating a voltage and is now 'dead'
A value for the cell potential of zero means that the reaction has reached equilibrium
If we change the concentration, we can change the magnitude of Ecell
This is now no longer a cell operating under standard conditions!
Changing concentrations in a galvanic cell
Standard conditions in a Zn/Zn2+ Cu2+/Cu cell
Zn (s) → Zn2+ (aq) + 2e– | Eo = -0.76 V | Oxidation |
Cu2+ + 2e– → Cu (s) | Eo = +0.34 V | Reduction |
Eo cell = Eored - Eoox
Eocell = 0.34 - (-0.76) = 1.10 V
If we change the concentrations to:
New Concentration | New Concentration |
---|---|
[Zn2+] = 5.00 M [Cu2+] = 1.00 M | [Zn2+] = 1.00 M [Cu2+] = 5.00 M |
Q = 5 | Q = 0.2 |
Ecell = 1.10 - 0.02 = 1.08 V which is now a lower value | Ecell = 1.10 - (-0.02) = 1.12 V which is now a higher value |
This is a deviation that takes the cell further from equilibrium than Q = 1 will increase the magnitude of the cell potential relative to Eocell | This is a deviation that takes the cell closer to equilibrium than Q = 1 will decrease the magnitude of the cell potential relative to Eocell |
Concentration Cells
A voltage can be generated by constructing an electrochemical cell in which each compartment contains the same redox active solution but at different concentrations
The voltage is produced as the concentrations equilibrate
For example, if we look at the following cell containing two different concentrations of zinc sulfate solution
Diagram to show two different concentrations of zinc sulfate in a concentration cell
Reduction occurs at the more concentrated half-cell and oxidation occurs at the less concentrated half-cell
The two different reactions taking place are
Oxidation occurs in the less concentrated half-cell:
Zn2+ (aq) (0.50 M) + 2e– → Zn (s)
Reduction occurs in the more concentrated half-cell:
Zn (s) → Zn2+ (aq) (1.00 M) + 2e–
So for this reaction, Ecell will = 0
Eocell = Eored - Eoox
Eocell = -0.76 - (-0.76) = 0.00 V
From the concentrations of the two different solutions of zinc sulfate, we can calculate the value for Q, or the reaction quotient
Q =
In this example Q =
Solids are not included in this calculation
Therefore, Ecell =
Ecell = 8.91 x 10-3 V
This is positive so is a spontaneous reaction
As the concentrations of each half cell get closer together over time, the value for Q will increase and Ecell will decrease
When Q = 1 the reaction will be in equilibrium and Ecell will be equal to 0
If there is no difference in concentration, there is no longer a requirement for concentrations to equalise which creates the potential difference in the cell
If Ecell = 0, then the cell is 'dead'
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