Pause for thought

Hess’s Law is named after Germain Henri Hess (1802 – 1850) a Swiss national who moved with his family to Russia at the age of 3. He qualified as a doctor but later became a professor of chemistry at the St Petersburg Technical Institute. He was interested in minerals and analyzed one particular ore of silver telluride, Ag₂Te, which is now called hessite in his honour.

Germain Hess                                                        Hessite

Hess’s Law states that the total energy change in a chemical reaction depends only upon the initial and final states and is independent of the reaction pathway. It used to be known as the Law of Constant Heat Summation and is in fact another way of stating the Law of Conservation of Energy.

So how can Hess’s Law be applied?

There are basically three different methods that can be used to solve Hess’s Law problems:

• Energy cycle
• Enthalpy level diagram
• Simultaneous equations

So which is the best method to train students to use?

Energy cycle, enthalpy level diagram or simultaneous equations?

Take as an example Question 15 on the SL Energetics/thermochemistry multiple choice test.

Qu.15. The enthalpy change for the dimerization of two mol of nitrogen dioxide to form one mol of dinitrogen tetroxide is – 57 kJ.

2NO₂(g) → N₂O₄(g)  ∆H = – 57 kJ

The enthalpy change for the formation of one mol of NO₂(g) from its elements is + 33 kJ

½ N₂(g) + O₂(g) → NO₂(g) ∆H = + 33 kJ

What is the enthalpy change for the formation of one mol of dinitrogen tetroxide from its elements?

N₂(g) + 2O₂(g) → N₂O₄(g)

1. Solution using simultaneous equations.

To get N₂ on the left hand side start with the second equation and double it:

N₂(g) + 2O₂(g) → 2NO₂(g) ∆H = + 66  kJ

To get rid of 2NO₂ and to get N₂O₄ on the right hand side add the first equation:

N₂(g) + 2O₂(g) → N₂O₄(g) ∆H = + 66 + (– 57) = + 9 kJ

Easy - but it does not really involve any chemistry.

2. Solution using an enthalpy diagram.

The problem is that you need to put the reactants and products in the correct places on the diagram.

Personally I do not find it very obvious from the information given even though there is no need to include the oxygen (as you do not know the answer beforehand) and students certainly do not find this easy.
Once the diagram has been drawn correctly it is easy to see that x is positive and is the difference in value between 66 and 57 kJ.

3. Solution using an energy cycle.

Use the idea of A going directly to B or via C. In this case A is N₂, B is N₂O₄ and C is NO₂.
In chemistry terms nitrogen can either be oxidized directly to N₂O₄ or first to NO₂ which then dimerizes
to N₂O₄. (Again there is no need to include the oxygen in the cycle.)

From the diagram (i.e. applying Hess’s Law) it is easy to see that x = (2 x 33) + (– 57) = + 9 kJ

All three methods are correct but I think the energy cycle method is the easiest, the most elegant and demonstrates the best understanding of chemistry.