The lead acid battery was developed more than 150 years ago. It is a low-cost rechargeable battery that provides the high current required by automobile starter motors. Lead-acid battery sales account for over 40% of the value from batteries sold world-wide. The following chemical reactions take place in the electrodes of this type of battery.

PbO₂(s) + HSO₄^–(aq) + 3 H⁺(aq)  ⇌  PbSO₄(s) + 2 H₂O(ℓ)

Pb(s) + HSO₄^–(aq)  ⇌  PbSO₄(s) + H⁺(aq)

1. Assign oxidation numbers to each atom in these half reactions. Complete each of these half reactions by representing the number of electrons consumed or generated in each case.
2. Identify which of these reactions takes place in the anode of the lead-acid battery and which reaction occurs in the cathode.
3. Draw a schematic diagram of a lead-acid battery cell showing the chemical composition and structure of each half-cell, as well as the flow of electric charge throughout the system.
4. The standard reduction potentials in the cathode and anode of a lead-acid battery are E° = 1.685 V and E° = –0.356 V, respectively. Compute the standard cell potential for this battery.
5. A typical car battery does not run under standard conditions. The concentration of the sulfuric acid (H₂SO₄, a strong acid that completely dissociates into H⁺ and HSO₄^– ions in aqueous solution) is close to 5 M.
   1. Write the overall chemical reaction for the lead-acid battery.
   2. Express the Nernst equation for a lead-acid battery and calculate its actual cell potential at 298 K.
   3. Express the Nernst equation for the battery as a function of pH (supposing for this exercise that [H⁺] and [HSO₄^–] stay equal and change together). Make a graph of cell potential vs. pH and discuss its implications for voltage and power.