To calculate the equilibrium constant Kc for the reaction, we first need to determine the standard cell potential E for the reaction. The standard cell potential can be calculated using the standard reduction potentials of the two half-reactions:E cell = E cathode - E anode Given the standard reduction potentials of A2+ 0.34 V and D2+ -0.74 V , we can identify the cathode and anode half-reactions:Cathode: A2+ + 2e- A E = 0.34 V Anode: D D2+ + 2e- E = 0.74 V, since the reduction potential is -0.74 V Now we can calculate the standard cell potential:E cell = 0.34 V - -0.74 V = 1.08 VNext, we can use the Nernst equation to relate the cell potential E at 25C to the standard cell potential E and the reaction quotient Q :E = E - RT/nF * ln Q At equilibrium, E = 0.60 V, and Q = Kc. We can rearrange the Nernst equation to solve for Kc:0.60 V = 1.08 V - RT/nF * ln Kc Let's plug in the values for R 8.314 J/molK , T 298 K , n 2, since there are 2 electrons transferred in the reaction , and F 96,485 C/mol :0.60 V = 1.08 V - 8.314 J/molK * 298 K / 2 * 96,485 C/mol * ln Kc Solving for Kc:ln Kc = 1.08 V - 0.60 V * 2 * 96,485 C/mol / 8.314 J/molK * 298 K ln Kc 10.61Now, we can find Kc by taking the exponent of both sides:Kc = e^10.61 40500So, the equilibrium constant Kc for the reaction at 25C is approximately 40,500.