Something to think about

Entropy is paradoxically probably one of the hardest and one of the easiest topics to learn! Hardest because a full understanding of entropy really requires knowledge of statistical thermodynamics; easiest because at this level it can be related simply to the idea of disorder and the questions asked in the examination are usually very straightforward.

 'Nature tends to disorder' is a very simplified form of the second law of thermodynamics (The total entropy change of an isolated system must be positive) will generally suffice to deduce whether an entropy change is positive or negative. It is actually better to understand that entropy refers to the distribution of available energy among the particles. The more ways the energy can be distributed the higher the entropy. However it can be quite difficult to understand why complex, highly ordered arrangements of molecules such as ice crystals form when water is cooled or even why humans exist. You need to understand the difference between an isolated system and a subsystem. While the entropy change within a subsystem (ice or humans) may become negative (i.e. more ordered) the total entropy change within the larger isolated system will be positive.

ΔS_total = ΔS_subsystem + ΔS_surroundings

Consider what happens when ice is added to water to cool a drink (left). When the ice melts it becomes more disordered (ΔS> 0) but the surrounding water in the glass becomes lower in temperature so therefore becomes more ordered (ΔS< 0). The heat gained by the ice must be equal to the heat lost by the water but overall the increase in disorder due to the ice melting is greater than the increase in order due to the surrounding water cooling.

The word 'spontaneous' provides a good example to use when discussing the importance of the correct use of language in chemistry. Language is one of the eight ways of knowing addressed in the TOK syllabus. Some students may have difficulty answering a question because they have not understood the language used in the question rather than the underlying chemical theory (see Language of Chemistry). In everyday English spontaneous means 'off the cuff' or carrying out an action or thought without prior preparation or considering all the consequences beforehand. In Chemistry it has a very different and highly specific meaning. According to sub-topic 15.2 all a Higher Level IB student needs to know is that a reaction will be spontaneous when ΔG is negative - but what does this really mean?

A spontaneous reaction is one that once initiated can proceed in a given direction without needing to be driven by the input of an external source of energy. In other words a spontaneous reaction releases free energy - that is energy that is available to do work¹. It does not necessarily mean the reaction must be exothermic or that there must be an increase in entropy as it depends upon a combination of both of these factors according to the equation ΔG = ΔH – TΔS.

Notice the use of the word 'can' rather than 'will' in the definition. In English spontaneous usually implies something done quite quickly. In chemistry there is no concept of time in the use of the word spontaneous. It says nothing about the rate of the reaction. Often a spontaneous reaction may not proceed at any measurable rate as the activation energy is so high. A good example is the combustion of carbon. Diamonds are pure carbon. In 2007 the artist Damien Hirst made a skull of diamonds (see image in 'Learning outcomes' above) called 'For the love of God'. Luckily for the group that bought it for one hundred million US dollars, diamonds are extremely stable kinetically in air even though, as ΔG for the combustion of carbon is negative, they are thermodynamically unstable and spontaneously burn to form carbon dioxide.

^1. Strictly speaking it is the ability to do external work. This is because ΔH is the enthalpy change at constant pressure and if there is a volume increase then internal work is done as the volume expands. This is beyond the syllabus as the IB does not distinguish between ΔH and the enthalpy change at constant volume, ΔU.