7.1 Equilibrium
Written specifically for students to provide help and support for the IB Diploma chemistry programme this page provides full coverage of the syllabus content of Topic 7.1 Equilibrium. It encourages you to think critically and provides many questions with full worked answers so that you can monitor and improve your knowledge and understanding.
Learning outcomes
After studying this topic you should be able to:
Understand
- In a closed system, equilibrium is reached when the rate of the forward reaction is equal to the rate of the reverse reaction.
- The equilibrium law describes how the equilibrium constant, Kc relates to the concentrations of the products and the reactants from which its value can be determined for a particular chemical reaction. The extent of a reaction at equilibrium is indicated by the magnitude of the equilibrium constant whose value is also dependent upon temperature.
- The position of the equilibrium changes with changes in concentration, pressure, and temperature.
- The relative amount of products and reactants present during a reaction at a particular point in time are given by the reaction quotient, Q. Q is the equilibrium expression using non-equilibrium concentrations.
- Adding a catalyst has no effect on the position of equilibrium or the equilibrium constant.
Apply your knowledge to:
- Characterize chemical and physical systems in a state of equilibrium.
- Deduce the equilibrium constant expression, Kc, from an equation for a homogeneous reaction.
- Determine the relationship between different equilibrium constants for the same reaction at the same temperature.
- Apply Le Chatelier’s principle to predict the qualitative effects of changes of temperature, pressure and concentration on the position of equilibrium and on the value of the equilibrium constant.
Relationships & vocabulary
Nature of science
The use of isotopic labelling to define equilibrium provides good evidence for a scientific theory. The term dynamic equilibrium is used in other contexts so is an example of the use of a common language across different disciplines although the chemistry definition may not always be born in mind.
International-mindedness
The Haber process has huge global significance as it has revolutionized world food production due to artificial fertilizers. However, because the oxidation of ammonia forms nitric acid, the precursor for many explosives, it
has also had a large impact on weaponry in many world conflicts.
For more examples and links to International mindedness, Theory of knowledge, utilization etc. see separate page which covers all of Topics 7 & 17: Equilibrium.
Vocabulary
dynamic | static | steady state | closed system |
macroscopic properties | homogeneous equilibria | heterogeneous equilibria | Le Chatelier's principle |
equilibrium law | equilibrium constant, Kc | reaction quotient, Q |
Learning slides
You can use this slide gallery for learning or for reviewing concepts and information. It covers all the key points in the syllabus for this sub-topic.
Something to think about
Once you have understood the concept of dynamic equilibrium (as opposed to static equilibrium) it is worth challenging yourself to think how it could be shown experimentally that either chemical or physical equilibrium is dynamic and not static. There are several ways in which it could be done but one of the most obvious is to use a radioactive isotope. Although the syllabus (sub-topic 2.1 The nuclear atom) does not require you to know specific isotopes, the dangers posed by 131-iodine in nuclear accidents are a good example of utilization and other specific isotopes are mentioned in several of the options.
Imagine pouring a saturated solution of potassium iodide (made with normal non-radioactive iodide ions) onto some solid potassium iodide containing 131-iodide ions. The mixture is then stirred and left for several hours. If the equilibrium was static then once the solid had been filtered from the solution the solution should not show any radioactivity as none of the iodide ions would have exchanged. However, if the iodide ions in solution are in dynamic equilibrium with the iodide ions in the solid then over time the solution will become increasingly more radioactive as more and more 131-iodide ions are incorporated into the solution.
This explains why normal iodine is kept as a safeguard at nuclear reactors. If there is an explosion or melt-down one of the radioactive products is 131-iodine. If it escapes, which did happen for real at the Fukushima nuclear reactor in Japan in 2011 (see above), then flooding the body with normal iodine helps to prevent, or at least minimise, 131-iodine being incorporated into humans via the hormone thyroxine.
You should be able to write equilibrium expressions and have some idea about what the size of the equilibrium constant tells you about the position of equilibrium. It is therefore reasonable to ask whether equilibrium constants have units. Consider the Contact process.
2SO2(g) + O2(g) ⇌ 2SO3(g)
You should be able to deduce that:
Since you have been told that [ ] means 'concentration', then in terms of units Kc is equal to concentration squared divided by concentration cubed which simplifies to one over concentration, or concentration−1. The units of the equilibrium constant, Kc, will therefore be mol−1 dm3. Using similar logic the units for the equilibrium constant for the Haber process will be concentration−2, or mol−2 dm6. In fact until 2007 the units of equilibrium constants was a specific assessment statement on the IB Chemistry Diploma programme and questions involving the units were often asked in the exams. The problem is that equilibrium constants do not in fact have units! The reasons is that the square brackets, [ ], actually mean activity rather than concentration and activity has no units. For this reason the values given for all equilibrium constants in examinations (and for Kw in the IB Data booklet) on the current syllabus do not have units.1
This can cause difficulties when comparing values of Kc for different reactions but not really for the IB, except for Higher Level students who are studying the environmental impact of heavy metals in Option A. The solubility product, Ksp, for silver chloride, AgCl, is 1.8 x 10-10 whereas the solubility product for silver chromate, Ag2CrO4, is 1.3 x 10-12. Although both are very 'insoluble' it would appear that silver chloride is more soluble as it has a higher Ksp value. However the concentration of silver ions in solution will be greater for silver chromate as the expression is [Ag+(aq)]2[CrO42-(aq)], i.e. concentration cubed, compared to the concentration squared expression, [Ag+(aq)][Cl-(aq)] for silver chloride.
Footnote
1 Actually in the current version of the IB data booklet (4th. edition dated JIB Docs (2) Teamary 2017) in Section 2 the ionic product for water, Kw is given units whereas the solubility product constants, Ksp given in Section 32 do not have units!
Test your understanding of this topic
(Note that your teacher may have restricted your access to some or all of these questions and worked answers if they are going to use them as a class test or set them as an assignment.)
For ten 'quiz' multiple choice questions with the answers explained see MC test: Equilibrium.
For short-answer questions see Equilibrium questions.
More resources
1. A video produced by the University of Surrey for revision purposes. It has quite a good illustration of the liquid water - water vapour equilibrium in open and closed systems.
2. A good video to illustrate Le Chatelier's principle. It shows how colourless SCN-(aq) ions and a very pale yellow solution of Fe3+(aq) ions react to form the red complex [Fe(H2O)5SCN]2+ ion using petri dishes and the effect of changing concentrations on the position of equilibrium.
3. A University of Surrey video which applies Le Chatelier's principle to the Haber process.
4. A good example of both concentration effect and le Chatelier's principle using a gas syringe filled with a mixture of NO2(g) and N2O4(g).
5. A really good and informative article on the Fritz Haber story which you might like to read. Also see the information given in 'Incorporating IM, TOK, 'Utilization etc. for Topics 7 & 17.