Gibbs Free Energy & the Equilibrium Constant
Gibbs Free Energy & the Equilibrium Constant
- The equilibrium constant, Kc, gives no information about the individual rates of reaction
- It is independent of the kinetics of the reaction
- The equilibrium constant, Kc, is directly related to the Gibbs free energy change, ΔGꝊ, according to the following (van't Hoff's) equation:
ΔGꝊ = -RT lnK
- ΔGꝊ= Gibbs free energy change (kJ mol–1)
- R = gas constant (8.31 J K-1 mol-1)
- T = temperature (Kelvin, K)
- K = equilibrium constant
- This equation is provided in section 1 of the data booklet
Exam Tip
When completing calculations using the ΔGꝊ = -RT lnK equation, you have to be aware that:
- ΔGꝊ is measure in kJ mol–1
- R is measured in J K-1 mol-1
This means that one of these values will need adjusting by a factor of 1000
- This relationship between the equilibrium constant, Kc, and Gibbs free energy change, ΔGꝊ, can be used to determine whether the forward or backward reaction is favoured
The relationship between the equilibrium constant, Kc, and Gibbs free energy change, ΔGꝊ
- At a given temperature, a negative ΔG value for a reaction indicates that:
- The reaction is feasible / spontaneous
- The equilibrium concentration of the products is greater than the equilibrium concentration of the reactants
- The value of the equilibrium constant is greater than 1
- As ΔG becomes more negative:
- The forward reaction is favoured more
- The value of the equilibrium constant increases