Answer:
Depending on the [tex]E^\circ[/tex] value of [tex]\rm Ag^{+} + e^{-} \to Ag\; (s)[/tex], the cell potential would be:
- [tex]0.55\; \rm V[/tex], using data from this particular question; or
- approximately [tex]0.46\; \rm V[/tex], using data from the CRC handbooks.
Explanation:
In this galvanic cell, the following two reactions are going on:
- The conversion between [tex]\rm Ag\; (s)[/tex] and [tex]\rm Ag^{+}[/tex] ions, [tex]\rm Ag^{+} + e^{-} \rightleftharpoons Ag\; (s)[/tex], and
- The conversion between [tex]\rm Cu\; (s)[/tex] and [tex]\rm Cu^{2+}[/tex] ions, [tex]\rm Cu^{2+}\; (aq) + 2\, e^{-} \rightleftharpoons \rm Cu\; (s)[/tex].
Note that the standard reduction potential of [tex]\rm Ag^{+}[/tex] ions to [tex]\rm Ag\; (s)[/tex] is higher than that of [tex]\rm Cu^{2+}[/tex] ions to [tex]\rm Cu\; (s)[/tex]. Alternatively, consider the fact that in the metal activity series, copper is more reactive than silver. Either way, the reaction is this cell will be spontaneous (and will generate a positive EMF) only if [tex]\rm Ag^{+}[/tex] ions are reduced while [tex]\rm Cu\; (s)[/tex] is oxidized.
Therefore:
- The reduction reaction at the cathode will be: [tex]\rm Ag^{+} + e^{-} \to Ag\; (s)[/tex]. The standard cell potential of this reaction (according to this question) is [tex]E(\text{cathode}) = 0.89\; \rm V[/tex]. According to the 2012 CRC handbook, that value will be approximately [tex]0.79\; \rm V[/tex].
- The oxidation at the anode will be: [tex]\rm Cu\; (s) \to \rm Cu^{2+} + 2\, e^{-}[/tex]. According to this question, this reaction in the opposite direction ([tex]\rm Cu^{2+}\; (aq) + 2\, e^{-} \rightleftharpoons \rm Cu\; (s)[/tex]) has an electrode potential of [tex]0.34\; \rm V[/tex]. When that reaction is inverted, the electrode potential will also be inverted. Therefore, [tex]E(\text{anode}) = -0.34\; \rm V[/tex].
The cell potential is the sum of the electrode potentials at the cathode and at the anode:
[tex]\begin{aligned}E(\text{cell}) &= E(\text{cathode}) + E(\text{anode}) \\ &= 0.89 \; \rm V + (-0.34\; \rm V) = 0.55\; \rm V\end{aligned}[/tex].
Using data from the 1985 and 2012 CRC Handbook:
[tex]\begin{aligned}E(\text{cell}) &= E(\text{cathode}) + E(\text{anode}) \\ &\approx 0.7996 \; \rm V + (-0.337\; \rm V) \approx 0.46\; \rm V\end{aligned}[/tex].
