To calculate the Gibbs free energy change G for the reaction, we can use the equation:G = H - TSwhere H is the change in enthalpy, T is the temperature in Kelvin, and S is the change in entropy.First, we need to find the change in enthalpy H for the reaction. We can do this using the given standard enthalpies of formation Hf for the reactants and products:H = [2 * Hf[H2O g ] - 2 * Hf[H2 g ] + Hf[O2 g ] ]H = [2 * -241.8 kJ/mol - 2 * 0 kJ/mol + 0 kJ/mol ]H = -483.6 kJ/molNext, we need to find the change in entropy S for the reaction. We can do this using the given standard entropies S for the reactants and products:S = [2 * S[H2O g ] - 2 * S[H2 g ] + S[O2 g ] ]S = [2 * 188.8 J/Kmol - 2 * 130.7 J/Kmol + 205.0 J/Kmol ]S = 377.6 J/Kmol - 261.4 J/Kmol + 205.0 J/Kmol S = 377.6 J/Kmol - 466.4 J/KmolS = -88.8 J/KmolNow, we can calculate the Gibbs free energy change G for the reaction using the equation:G = H - TSG = -483.6 kJ/mol - 298 K * -88.8 J/Kmol Since we need to convert J to kJ, we divide by 1000:G = -483.6 kJ/mol - 298 K * -0.0888 kJ/Kmol G = -483.6 kJ/mol + 26.5 kJ/molG = -457.1 kJ/molThe Gibbs free energy change for the reaction 2H2 g + O2 g 2H2O g at standard conditions 298 K and 1 atm pressure is -457.1 kJ/mol.