Pause for thought

The chemistry covered in this part of sub-topic 10.2 is really very simple. It can be summarized by saying that alcohols burn in oxygen to give carbon dioxide and water, primary alcohols are oxidised first to aldehydes then carboxylic acids, secondary alcohols are oxidized to ketones and tertiary alcohols cannot be oxidized whilst still retaining the carbons chain. All alcohols can react with carboxylic acids to form esters. This condensation reaction is also known as esterification. Be careful to stress that although the class of compounds is correctly called alcohols the IB calls the -OH functional group the hydroxyl group, although probably it is more correct to call it the hydroxy group so that, for example, the systematic (IUPAC) name of lactic acid, CH₃CH(OH)COOH is 2-hydroxypropanoic acid, not 2-hydroxylpropanoic acid.

In fact alcohols, and ethanol in particular, provide a useful respite from the purely organic chemistry approach. Ethanol has many attributes similar to water – or put another way the simplest 'alcohol' of all is water, H-O-H. It could be worth considering using ethanol (and the other alcohols) to re-enforce the chemistry of some of the other core topics.

For example:

Topic 1. (1.1) Deduction of chemical equations when reactants and products are specified.
Student should be able to deduce a general equation for the combustion of any alcohol C_xH_yO.
C_xH_yO + (x + y/4 -½)O₂ → xCO₂ + y/2H₂O

Topic 3. (3.2) Group trends should include the treatment of the reactions of alkali metals with water.
You could ask students to deduce what might happen if a very small piece of sodium metal is placed in ethanol rather than water. From the equation with water they should be able to work out that hydrogen gas will be evolved.

Na(s) + H-O-H(l) → Na⁺(aq) + OH^–(aq) + ½H₂(g)
Na(s) + R-O-H(l) → Na⁺(aq) + OR^–(aq) + ½H₂(g)

The reaction of alcohols with sodium is not actually on the IB programme but it does help to re-enforce the understanding of the reaction of sodium with water.

Topic 4. (4.3) Prediction of molecular polarity from bond polarity and molecular geometry.
By substituting just one of the hydrogen atoms in water with a –C₂H₅ group students can easily see that ethanol is polar. They should also be able to deduce that it is not as polar as water as there is only one hydrogen atom with δ+, not two . An interesting demonstration is to put a beaker of water (about 10 cm³) in a household microwave oven for ten seconds or so and record the temperature rise. Ask students what will happen if you repeat it with 10 cm³ of ethanol. They will probably predict the temperature will not rise as much as it is less polar. In fact it will rapidly boil as its specific heat capacity is lower.

Topic 5. (5.1) A calorimetry experiment for an enthalpy of reaction should be covered and the results evaluated.
Combusting alcohols using a spirit lamp under a calorimeter and then determining the enthalpy change is a classic experiment.

Topic 6. (6.1) Explanation of the effects of temperature on rate of reaction and (6.1.) Investigation of rates of reaction experimentally and evaluation of the results.
The obvious link with Topic 6 is that heat is required to bring about the oxidation of primary and secondary alcohols with an acidified solution of potassium dichromate(VI). The heat, of course increases the energy of the reacting particles so that more will have the necessary activation energy for the reaction to proceed. However if you got them to deduce what will happen when sodium metal is reacted with ethanol (see Topic 1 above) then you could ask them to design or investigate an experiment to measure the rate when different alcohols are used (e.g. CH₃OH, C₂H₅OH, C₃H₇OH and C₄H₉OH) to see what happens to the reaction rate when the carbon chain length increases.

Topic 7. (7.1) Deduction of the equilibrium constant expression (K_c) from an equation for a homogeneous reaction.
One of the classic reactions used to illustrate homogeneous equilibrium is the esterification reaction between ethanol and ethanoic acid. You could even bring in a bit of Topic 2 here and ask them how they could determine whether it is the oxygen atom from the alcohol or the carboxylic acid that ends up in the water. The answer of course is to use isotopic labelling with ¹⁸O.

Topic 8. (8.1.) Deduction of the conjugate acid or conjugate base in a chemical reaction.
Students know that hydroxide ions are a strong base. This is because hydroxide ions are the conjugate base of water which is a very weak acid (K_w = 1.00 x 10^-14). Ethanol is an even weaker acid (K_a = approximately 10^-16) so they should be able to deduce that the ethoxide ion, C₂H₅O^–, is an even stronger base than the hydroxide ion, OH^–.

Topic 9. (9.1) Deduction of redox reactions using half-equations in acidic or neutral solutions.
Often when writing the alcohol oxidation equations in Topic 10 [O] is used to represent the oxygen from the oxidizing agent. But under topic 9 students could be asked to write the full equation and even in Topic 10 this is still true as it  states under 'Applications and skills', "Writing equations for the oxidation reactions of primary and secondary alcohols(using acidified potassium dichromate(VI) or potassium manganate(VII)  as oxidizing agents).". So give them the half-equations for the reduction of dichromate(VI) ions and manganate(VII) ions in acidic solution and ask them to deduce the balanced redox equations for the oxidation of ethanol to ethanal and then to ethanoic acid. It is all good practice.

Topic 11. (11.1) Uncertainties and errors in measurement and results.
If you have got this far, you deserve an alcoholic drink. It is bound to increase the uncertainty and error in your measurements.