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πŸ§ͺ Corrosion and Its Prevention

Spec 4.10.3.1 πŸ“™ Higher
πŸ“– In-Depth Theory

Corrosion and Rusting

CORROSION is the destruction of materials by chemical reactions with substances in the environment.
RUSTING β€” corrosion of iron:
Iron reacts with oxygen AND water to form hydrated iron(III) oxide (rust).
Both air AND water are necessary β€” iron will not rust in dry air alone or in pure water without dissolved oxygen.
Chemical equation:
4Fe + 3Oβ‚‚ + 2xHβ‚‚O β†’ 2Feβ‚‚O₃·xHβ‚‚O (rust)
Rusting is an OXIDATION reaction β€” iron loses electrons (Fe β†’ Fe²⁺ β†’ Fe³⁺).
FACTORS THAT SPEED UP RUSTING:
Salt water (electrolyte) β€” increases electrical conductivity β†’ speeds up electrochemical corrosion.
Acidic conditions β€” lower pH speeds up the reaction.
Contact with a more reactive metal β€” galvanic corrosion.
ALUMINIUM:
Aluminium is MORE reactive than iron but resists corrosion in air.
Reason: forms a thin, DENSE OXIDE LAYER (Alβ‚‚O₃) on the surface.
This oxide layer is IMPERMEABLE β€” prevents further reaction.
Protects the metal underneath β€” called PASSIVATION.

Methods of Preventing Corrosion

All prevention methods work by either:
(a) Creating a BARRIER between the metal and oxygen/water, or
(b) Using SACRIFICIAL PROTECTION β€” a more reactive metal corrodes instead.
1. PAINTING:
Barrier coating β€” widely used on cars, ships, bridges.
Must be maintained β€” if paint chips, corrosion begins.
2. GREASING/OILING:
Barrier coating for moving parts β€” chains, hinges, machinery.
Prevents water and oxygen reaching the surface.
3. ELECTROPLATING:
Coating with another metal (e.g. chromium, tin, zinc) by electrolysis.
Chromium plating: shiny, decorative and corrosion-resistant.
Tin plating: used in food cans β€” tin is less reactive than iron, non-toxic.
4. GALVANISING β€” coating with ZINC:
Zinc is MORE REACTIVE than iron.
Two effects: (a) barrier coating; (b) sacrificial protection.
If zinc coating is scratched, zinc still protects iron β€” zinc corrodes preferentially.
5. SACRIFICIAL PROTECTION:
Attach a MORE REACTIVE metal to the structure.
The reactive metal corrodes instead of the iron.
Examples: zinc blocks on ship hulls; magnesium blocks on underground steel pipes.
Must be replaced periodically as the sacrificial metal is consumed.

Choosing the Right Method

The choice of prevention method depends on:
COST β€” painting is cheap; electroplating more expensive.
WHERE the metal is used β€” underwater requires sacrificial protection; indoor items can use paint.
APPEARANCE β€” chromium plating gives shiny decorative finish.
DURABILITY β€” galvanising outlasts paint for outdoor structures.
FOOD CANS β€” tin plating:
Tin is less reactive than iron β€” acts as barrier.
If tin layer is scratched: iron corrodes faster (galvanic cell β€” iron = anode).
This is why dented cans should be discarded β€” exposed iron rusts rapidly.
SHIPS AND OFFSHORE STRUCTURES:
Paint + sacrificial zinc/magnesium blocks.
Blocks regularly inspected and replaced.
BRIDGES:
Regular repainting β€” Forth Bridge famously requires continuous painting.
New bridges: weathering steel (forms protective rust layer) or galvanised steel.
⚠️ Common Mistake

Iron needs BOTH oxygen AND water to rust β€” not just one of them. Aluminium doesn't corrode despite being reactive because it forms an impermeable OXIDE LAYER. Galvanising uses zinc β€” zinc is more reactive than iron and provides SACRIFICIAL PROTECTION even if the coating is scratched.

πŸ“ Key Equations
4Fe + 3Oβ‚‚ + 2xHβ‚‚O β†’ 2Feβ‚‚O₃·xHβ‚‚O (rusting)
πŸ“Œ Key Note

Corrosion: destruction of metal by environment. Rusting: iron + Oβ‚‚ + Hβ‚‚O β†’ rust (both needed). Prevention: painting, greasing, electroplating, galvanising (zinc β€” barrier + sacrificial). Sacrificial protection: attach more reactive metal β€” it corrodes instead. Aluminium: self-protecting via oxide layer.

🎯 Matching Activity β€” Corrosion Prevention Methods

Match each method to how it prevents corrosion. β€” drag the symbols on the right to match the component names on the left.

Painting
Drop here
Galvanising (zinc coating)
Drop here
Sacrificial protection
Drop here
Aluminium oxide layer
Drop here
Creates a physical barrier β€” excludes oxygen and water from the metal surface
Self-protecting β€” impermeable Alβ‚‚O₃ layer prevents further oxidation of the aluminium underneath
Barrier + sacrificial β€” zinc corrodes instead of iron even if coating is scratched
More reactive metal attached β€” corrodes preferentially, protecting the iron/steel structure
⭐ Higher Tier Only

Write half equations for the electrochemical process of rusting: Fe β†’ Fe²⁺ + 2e⁻ (anode); Oβ‚‚ + 4H⁺ + 4e⁻ β†’ 2Hβ‚‚O (cathode). Explain sacrificial protection as a galvanic cell process. Evaluate anti-corrosion methods for cost-effectiveness in specific engineering contexts.

πŸ”¬ Triple Science Only

Corrosion and its prevention (4.10.3.1) is chemistry-only β€” not in Combined Science.

🎯 Test Yourself
Question 1 of 2
1. Iron rusts quickly in seawater but slowly in pure water. Why?
2. Why does galvanising protect steel even after the zinc coating is scratched?
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