For the given cell: The standard cell potential of the above reaction is given. The standard reduction potentials are given as: The correct answer is:
- A
- B
- C
- D
For the given cell: The standard cell potential of the above reaction is given. The standard reduction potentials are given as: The correct answer is:
Correct answer:B
Standard Method
Given: The cell reaction is . The given standard reduction potentials are , and .
Find: The expression for the standard cell potential.
At the cathode, silver ion is reduced:
So its reduction potential is .
To obtain the reduction potential, combine the given iron reduction reactions through Gibbs energy additivity, which gives:
But in the cell reaction, iron undergoes oxidation:
Therefore the corresponding oxidation potential is the negative of the above reduction potential.
Hence the standard cell potential is
Therefore, the correct option is B and the standard cell potential is .
The solution contains inconsistent intermediate statements, but its final conclusion and listed correct option both indicate .
Deriving the $$Fe^{3+}/Fe^{2+}$$ potential
Use the two given iron reduction half-reactions:
Reverse the second reaction to write oxidation of iron metal to :
Add it to the first reaction:
This gives
Using ,
So,
Now apply
with cathode potential and anode reduction potential :
Therefore, the correct option is B.
Using values directly like ordinary algebraic quantities is incorrect when combining half-reactions. First convert through , then recompute the net potential.
Treating as if its potential were simply is wrong. The given iron half-reactions involve different electron counts, so the one-electron couple must be derived carefully.
Forgetting that the anode process in the cell is oxidation leads to sign errors. Use the reduction potential of the anode couple in , or reverse the sign consistently if writing oxidation potential.
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