In the previous question, you had to calculate the the standardFree Energy Change (?G^o) in order to solve for theequilibrium constant, K, for the reaction:

N₂(g) + 3H₂(g) ?2NH₃(g)

This is the Free Energy measured under standardconditions, when the reaction is started with 1.0 M ofeach of the three gases present. Calculate thenon-standard Free Energy change (?G) at 298 K,given the following non-standard initial partial pressures of thethree gases. Answer in kJ.
?G_f^o = -16.6 kJ/mol for NH₃ (g) at298 K

	partial pressure (atm)
N2	1.0
H2	0.04
NH3	1.9

? G =

N2(g) + 3H2(g) → 2NH3(g) This is the Free Energy measured under standard conditions, when the reaction is started with 1.0 M of each of the three gases present. Calculate the non-standard Free Energy change (∆G) at 298 K, given the following non-standard initial concentrations of the three gases. Answer in kJ. ∆Gfo = -16.6 kJ/mol for NH3 (g) at 298 K initial concentration (M) N2 1.0 H2 0.1 NH3 4.8

Calculate the free-energy change for ammonia synthesis at 25oC given the following sets of partial pressures:

(a) 1.0 atm N2, 3.0 atm H2, 0.020 atm NH3

(b) 0.010 atm N2, 0.030 atm H2, 2.0 atm NH3

N2(g) + 3H2(g)--->2NH3(g) DeltaG* = -33.0 kJ

For a gaseous reaction, standard conditions are 298 K and a partial pressure of 1 atm for all species. For the reaction

N2(g) +3H2(g) --->2NH3

the standard change in Gibbs free energy is ΔG° = -32.8 kJ/mol. What is ΔG for this reaction at 298 K when the partial pressures are

PN2=0.100atm PH2=0.300atm PNH3=0.905atm