Finding the formula of hydrated copper(II) sulfate
Description
In this experiment, the water of crystallisation is removed from hydrated copper(II) sulfate. The mass of water is found by weighing before and after heating. This information is used to find x in the formula: CuSO4.xH2O.
In this experiment, the water of crystallisation is removed from hydrated copper(II) sulfate. The mass of water is found by weighing before and after heating. This information is used to find x in the formula: CuSO4.xH2O.
This is a class experiment suitable for students who already have a reasonable understanding of the mole concept.
The degree to which the mole calculations need to be structured will depend on the ability and mathematical competence of the class. The outline structure given in the Procedure above is intended for students with reasonable mathematical competence and experience of mole calculations.
Given adequate access to top-pan balances, and skill in their use, students should be able to complete the experimental work in 30-40 minutes.
Apparatus
Chemicals
Eye protection
Each working group will require:
Crucible (Note 1)
Crucible tongs (Note 2)
Tripod
Pipe-clay triangle
Bunsen burner
Heat resistant mat
Top-pan balance (± 0.01 g)
Hydrated copper(II) sulfate (HARMFUL, DANGEROUS FOR THE ENVIRONMENT), 2 - 3 g
Refer to Health & Safety and Technical notes section below for additional information.
Hydrated copper(II) sulfate, CuSO4.5H2O(s), (HARMFUL, DANGEROUS FOR ENVIRONMENT) - see CLEAPSS Hazcard. The copper(II) sulfate should be provided as fine crystals. If large crystals are used, these should be ground down before use by students.
1 Crucibles may be of porcelain, stainless steel or nickel, of capacity about 15 cm3, and should sit safely in the pipe-clay triangles provided.
2 Crucible tongs should have a bow in the jaws of the right size to pick up the hot crucibles safely.
Procedure
a Weigh the empty crucible, and then weigh into it between 2 g and 3 g of hydrated copper(II) sulphate. Record all weighings accurate to the nearest 0.01 g.
b Support the crucible securely in the pipe-clay triangle on the tripod over the Bunsen burner.
c Heat the crucible and contents, gently at first, over a medium Bunsen flame, so that the water of crystallisation is driven off steadily. The blue colour of the hydrated compound should gradually fade to the greyish-white of anhydrous copper(II) sulfate. Avoid over-heating, which may cause further decomposition, and stop heating immediately if the colour starts to blacken. If over-heated, toxic or corrosive fumes may be evolved. A total heating time of about 10 minutes should be enough.
d Allow the crucible and contents to cool. The tongs may be used to move the hot crucible from the hot pipe-clay triangle onto the heat resistant mat where it should cool more rapidly.
e Re-weigh the crucible and contents once cold.
f Calculation:
Calculate the molar masses of H2O and CuSO4 (Relative atomic masses: H=1, O=16, S=32, Cu=64)
Calculate the mass of water driven off, and the mass of anhydrous copper(II) sulfate formed in your experiment
Calculate the number of moles of anhydrous copper(II) sulfate formed
Calculate the number of moles of water driven off
Calculate how many moles of water would have been driven off if 1 mole of anhydrous copper(II) sulfate had been formed
Write down the formula for hydrated copper(II) sulfate.
Teaching notes
Remind students to zero (tare) the balance before each weighing.
Students will probably also have to be reminded about the need to allow the crucible and contents to cool thoroughly before weighing.
Metal crucibles (stainless steel or nickel) are much less vulnerable than porcelain crucibles.
Health & Safety checked, 2016
Credits
This Practical Chemistry resource was developed by the Nuffield Foundation and the Royal Society of Chemistry.
In this experiment, the water of crystallisation is removed from hydrated copper(II) sulfate. The mass of water is found by weighing before and after heating. This information is used to find x in the formula: CuSO
4
.xH
2
O.
This is a resource from the Practical Chemistry project, developed by the Nuffield Foundation and the Royal Society of Chemistry. This collection of over 200 practical activities demonstrates a wide range of chemical concepts and processes. Each activity contains comprehensive information for teachers and technicians, including full technical notes and step-by-step procedures. Practical Chemistry activities accompany
Practical Physics
and
Practical Biology
.