The cell notation Zn(s)|Zn^{2+}(aq)|Cu^{2+}(aq)|Cu(s) represents a galvanic cell operating under standard conditions - NSC Technical Sciences - Question 6 - 2020 - Paper 2

The diagram of the Zn-Cu galvanic cell includes:

• Anode: Zn electrode in ZnSO₄ solution
• Cathode: Cu electrode in CuSO₄ solution
• Salt bridge: connects the two half-cells
• Voltmeter: measures the voltage developed by the cell

The direction of electron flow is from the anode (Zn) to the cathode (Cu).

1. The temperature should be 25°C.
2. The concentration of the electrolytes should be 1 mol/dm³.

The anions in the salt bridge migrate towards the anode half-cell.

Anions migrate towards the anode to maintain electrical neutrality in the cell. As oxidation occurs at the anode, positive charge builds up there, which needs to be balanced by the flow of anions from the salt bridge.

Given that the cell potential (E) is 2.00 V and that Cu²⁺/Cu is the cathode, we can use the Nernst equation to identify Electrode X. Assuming electrode X is aluminum (Al), and calculating its standard reduction potential gives:
E°{cell} = E°{cathode} - E°{anode} 2.00 V = E°{Cu²⁺/Cu} - E°_{Al³⁺/Al} Thus, Electrode X is aluminum.

At the anode where zinc oxidation occurs:
Zn(s) → Zn²⁺(aq) + 2e⁻.

The anode, where zinc is oxidized, will experience a decrease in mass as Zn atoms are converted to Zn²⁺ ions.

The anode will decrease in mass because the zinc solid is oxidized to zinc ions, which enter the solution. This oxidation results in the loss of material from the anode, causing its mass to decrease.