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The Nernst Equation Standard potentials assume a concentration of 1 M. The Nernst equation allows us to calculate potential when the two cells are not.

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Presentation on theme: "The Nernst Equation Standard potentials assume a concentration of 1 M. The Nernst equation allows us to calculate potential when the two cells are not."— Presentation transcript:

1 The Nernst Equation Standard potentials assume a concentration of 1 M. The Nernst equation allows us to calculate potential when the two cells are not 1.0 M. R = 8.31 J/(mol  K) T = Temperature in K n = moles of electrons in balanced redox equation F = Faraday constant = 96,485 coulombs/mol e -

2 Nernst Equation Simplified At 25  C (298 K) the Nernst Equation is simplified this way:

3 Equilibrium Constants and Cell Potential At equilibrium, forward and reverse reactions occur at equal rates, therefore: 1. 1. The battery is “dead” 2. The cell potential, E, is zero volts Modifying the Nernst Equation (at 25  C):

4 Zn + Cu 2+  Zn 2+ + Cu E 0 = + 1.10 V Calculating an Equilibrium Constant from a Cell Potential

5 Concentration Cell Step 1: Determine which side undergoes oxidation, and which side undergoes reduction. Both sides have the same components but at different concentrations. ???

6 Concentration Cell Both sides have the same components but at different concentrations. The 1.0 M Zn 2+ must decrease in concentration, and the 0.10 M Zn 2+ must increase in concentration Zn 2+ (1.0M) + 2e -  Zn (reduction) Zn  Zn 2+ (0.10M) + 2e - (oxidation) ??? Cathode Anode Zn 2+ (1.0M)  Zn 2+ (0.10M)

7 Concentration Cell Step 2: Calculate cell potential using the Nernst Equation (assuming 25  C). Both sides have the same components but at different concentrations. ??? Cathode Anode Zn 2+ (1.0M)  Zn 2+ (0.10M) Concentration Cell

8 Nernst Calculations Zn 2+ (1.0M)  Zn 2+ (0.10M)

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