Determining Relative Concentration
Using a titration to prepare a soluble salt
- Titrations can be used to prepare a soluble salt e.g. sodium chloride from an acid and alkali
- The acid and alkali are reacted together in a neutralisation reaction
- When the acid and alkali are completely neutralised only a salt and water will be present in the solution
hydrochloric acid + sodium hydroxide → sodium chloride + water
HCl (aq) + NaOH (aq) → NaCl (aq) + H2O (l)
Steps to prepare a soluble salt
Diagram showing the apparatus needed to prepare a salt by titration
Method:
- Use a pipette to measure a fixed volume of alkali into a conical flask and add a few drops of an indicator
- Add the acid into the burette and note the starting volume
- Add the acid very slowly from the burette to the conical flask until the indicator changes to the appropriate colour
- Note and record the final volume of acid in the burette and calculate the volume of acid added (final volume of acid - initial volume of acid)
- Add this same volume of acid into the same volume of alkali without the indicator
- Heat the resulting solution in an evaporating basin to partially evaporate, leaving a saturated solution (crystals just forming on the sides of the basin or on a glass rod dipped in and then removed)
- Leave to crystallise, decant excess solution and allow crystals to dry
Exam Tip
Make sure you learn the steps for how to prepare a soluble salt using:
- An acid and insoluble base
- A titration
For the second method, many students forget the step of not adding an indicator so make sure you add this in.
Determining the relative concentration of acids and alkalis
- If an alkali of known concentration is used in a titration then the relative concentration of the acid can be determined and vice versa
- This is done by looking at the volumes of each reactant
- If the volume of acid used is the greatest then the acid is less concentrated
- This is because more acid is required to neutralise the alkali
- If the volume of alkali used is the greatest then the alkali is less concentrated for the same reasons
- This is true of neutralisation reactions where the ratio of acid to alkali is 1:1
- For example, if 30.00 cm3 of 0.2 mol dm–3 acid is neutralised by 15.00 cm3 of an unknown alkali, the concentration of the alkali must be twice the concentration of the acid
- This is because only half the volume of the alkali is required to neutralise 30.00 cm3 of acid
- The method to carry out a titration can be found here
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= 0.59 mol dm–3 to 2 dp
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= 0.040 dm3