In order to obtain 1 tonne of aluminium, the following inputs are required: 4 tonnes of bauxite, 150 kg of sodium hydroxide and 600 kg of graphite. The aluminium compound in bauxite is aluminium oxide and the main impurity is iron (III) oxide. Aluminium is obtained by the electrolysis of aluminium oxide dissolved in cryolite.
(a) When bauxite is treated with sodium hydroxide solution, what happens to
(i) the aluminium oxide
(ii) the iron (III) oxide
(b) (i) Name the process used for the purification of bauxite.
(ii) Write the equation for the action of heat on aluminium hydroxide.
(c) (i) Write the formula of cryolite.
(ii) Write down the word which correctly completes the following sentence:
By dissolving aluminium oxide in cryolite a ............... (conducting/non-conducting) solution is produced.
(iii) Why is so much graphite required for the electrolytic process?
(iv) Write the equation for the reaction which takes place at the cathode
(v) What is the cathode made up of?
(a) Aluminium oxide dissolves and forms sodium meta aluminate. Iron (III) oxide is left behind as red mud and is removed by filtration.
Al2O3.2H2O + 2NaOH ⟶ 2NaAlO2 + 3H2O
(b) (i) Bayer's process
(ii) The equation for the action of heat on aluminium hydroxide is:
(c) (i) Na3AlF6
(ii) By dissolving aluminium oxide in cryolite, a conducting solution is produced.
(iii) Thick Graphite rods attached to copper clamps dipping into fused electrolyte are used as anode. The graphite (anode) is oxidized by oxygen to CO and further forms CO2, so it is consumed and has to be replaced from time to time. Hence, large amount of graphite is required.
Equation:
2C + O2 ⟶ 2CO
2CO + O2 ⟶ 2CO2
(iv) Reaction at the cathode:
4Al3+ + 12e- ⟶ 4Al
(v) Inner carbon lining of the electrolytic cell
Chapter Overview: Metallurgy
Metallurgy is the process of extracting metals from their ores and refining them for use. Metals occur in nature as free elements (gold, silver) or combined in ores (oxides, sulphides, carbonates). The extraction process depends on the metal's reactivity: highly reactive metals (Na, Al) are extracted by electrolysis, moderately reactive metals (Fe, Zn) by reduction with carbon, and least reactive metals (Cu, Hg) by simple heating. The general steps include mining, crushing and concentration of ore, extraction (reduction), and refining. Students must understand the extraction of aluminium (electrolysis of alumina in cryolite), iron (blast furnace), and zinc (reduction of ZnO with carbon). The reactivity series determines the method of extraction: metals above carbon require electrolysis; metals below carbon can be reduced by carbon. The chapter also covers alloys (mixtures of metals or metals with non-metals), their composition and uses, and the concept of corrosion and its prevention.
Key Concepts & Reactions
| Term / Process | Details |
|---|---|
| Ore | Mineral from which a metal can be profitably extracted |
| Gangue | Earthy impurities present in the ore |
| Calcination | Heating ore strongly in limited air to remove moisture and CO2 |
| Roasting | Heating ore in excess air to convert sulphides to oxides |
| Smelting | Reduction of metal oxide using carbon or CO in a furnace |
| Flux | Substance added to remove gangue by forming fusible slag |
| Slag | Fusible product of flux + gangue (e.g., CaSiO3) |
| Alloy | Homogeneous mixture of two or more metals (or metal + non-metal) |
Must-Know Concepts
- Blast furnace reactions for iron extraction: Fe2O3 + 3CO → 2Fe + 3CO2
- Coke burns: C + O2 → CO2; then CO2 + C → 2CO (reducing agent)
- Limestone acts as flux: CaCO3 → CaO + CO2; then CaO + SiO2 → CaSiO3 (slag)
- Aluminium extraction: Al2O3 dissolved in cryolite (Na3AlF6), electrolysed at ~950°C
- Common alloys: Brass (Cu + Zn), Bronze (Cu + Sn), Steel (Fe + C), Stainless Steel (Fe + Cr + Ni + C)
- Corrosion prevention: painting, galvanising, electroplating, alloying
Calcination vs Roasting
| Feature | Calcination | Roasting |
|---|---|---|
| Air Supply | Limited or no air | Excess air |
| Ore Type | Carbonates and hydrated ores | Sulphide ores |
| Gas Evolved | CO2 and water vapour | SO2 |
| Example | ZnCO3 → ZnO + CO2 | 2ZnS + 3O2 → 2ZnO + 2SO2 |
Important Diagrams to Practice
- Labelled diagram of the blast furnace with temperature zones and reactions
- Electrolytic cell for aluminium extraction (Hall-Heroult process)
- Flowchart of general metallurgical steps: ore → concentration → extraction → refining
Common Mistakes
- Confusing calcination (limited air, carbonates) with roasting (excess air, sulphides)
- Saying "coke reduces iron oxide" directly (CO is the actual reducing agent, not C)
- Writing wrong alloy compositions (brass is Cu+Zn, NOT Cu+Sn which is bronze)
- Forgetting the role of cryolite in aluminium extraction (lowers melting point)
Scoring Tips
- Draw and label the blast furnace diagram neatly - this is a very common question
- Write balanced equations for each zone of the blast furnace
- Memorise alloy compositions and uses as a table for quick revision
- Link extraction method to position in the reactivity series
Frequently Asked Questions
Why can't aluminium be extracted by carbon reduction?
Aluminium is above carbon in the reactivity series, so carbon cannot reduce Al2O3. Electrolysis of molten alumina (with cryolite) is required to extract aluminium.
What is the role of limestone in the blast furnace?
Limestone (CaCO3) decomposes to CaO, which acts as a flux. It combines with silica (SiO2, the gangue) to form calcium silicate slag (CaSiO3), which floats on molten iron and is removed.
Why are alloys preferred over pure metals?
Alloys are harder, stronger, more resistant to corrosion, and have better properties than pure metals. For example, stainless steel resists rusting unlike pure iron, and brass is harder than pure copper.