Gibbs Free Energy
Gibbs free energy
- The feasibility of a reaction is determined by two factors, the enthalpy change and the entropy change
- The two factors come together in a fundamental thermodynamic concept called the Gibbs free energy (G)
- The Gibbs equation is:
ΔGꝋ = ΔHreactionꝋ – TΔSsystemꝋ
-
- The units of ΔGꝋ are in kJ mol–1
- The units of ΔHreactionꝋ are in kJ mol–1
- The units of T are in K
- The units of ΔSsystemꝋ are in J K-1 mol–1 (and must therefore be converted to kJ K–1 mol–1 by dividing by 1000)
Calculating ΔGꝋ
- There are two ways you can calculate the value of ΔGꝋ
- From the Gibbs equation, using enthalpy change, ΔHꝋ, and entropy change, ΔSꝋ, values
- From ΔGꝋ values of all the substances present
Worked example
ΔGꝋ from ΔHꝋ and ΔSꝋ values
Calculate the free energy change for the following reaction at 298 K:
2NaHCO3 (s) → Na2CO3 (s) + H2O (l) + CO2 (g)
- ΔHꝋ = +135 kJ mol-1
- ΔSꝋ = +344 J K-1 mol-1
Answer:
- Step 1: Convert the entropy value in kilojoules
- ΔSꝋ =
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= +0.344 kJ K-1 mol-1
- ΔSꝋ =
- Step 2: Substitute the terms into the Gibbs Equation
- ΔGꝋ = ΔHreactionꝋ – TΔSsystemꝋ
- ΔGꝋ = +135 – (298 x 0.344)
- ΔGꝋ = +32.49 kJ mol-1
Worked example
ΔGꝋ from other ΔGꝋ values
What is the standard free energy change, ΔGꝋ, for the following reaction?
C2H5OH (l) + 3O2 (g) → 2CO2 (g) + 3H2O (g)
| Substance | ΔGꝋ kJ mol-1 |
| C2H5OH (l) | -175 |
| O2 (g) | 0 |
| CO2 (g) | -394 |
| H2O (g) | -229 |
Answer:
- This can be calculated in the same way as you complete enthalpy calculations
- ΔGꝋ = ΣΔGproductsꝋ – ΣΔGreactantsꝋ
- ΔGꝋ = [(2 x CO2 ) + (3 x H2O )] – [(C2H5OH) + (3 x O2)]
- ΔGꝋ = [(2 x -394 ) + (3 x -229 )] – [-175 + 0]
- ΔGꝋ = -1300 kJ mol-1
- This can also be done by drawing a Hess cycle - find the way that is best for you
Exam Tip
- The idea of free energy is what’s ‘leftover’ to do useful work when you’ve carried out the reaction
- The enthalpy change is the difference between the energy you put in to break the chemical bonds and the energy out when making new bonds
- The entropy change is the ‘cost’ of carrying out the reaction, so free energy is what you are left with!
