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Limestone [GCSE Chemistry only]Stability of metal carbonates

This topic covers the thermal stabilities of different metal carbonates, as well as specific reactions and uses of limestone (calcium carbonate) and the wider implications of its use.

Part of Chemistry (Single Science)Limestone

Stability of metal carbonates

One common reaction of any metal is known as thermal decomposition. When metal carbonates are heated, they break down to form the metal oxide and carbon dioxide gas. Here are some examples.

sodium carbonate → sodium oxide + carbon dioxide

Na2CO3(s) → Na2O(s) + CO2(g)

copper(II) carbonate → copper(II) oxide + carbon dioxide

CuCO3(s) → CuO(s) + CO2(g)

The difficulty of this decomposition reaction depends on the reactivity of the metal in the metal carbonate. If we take the two examples above, sodium is a very reactive metal. This means that sodium carbonate is very stable and requires a high temperature to decompose. However, copper is a very unreactive metal, which is why it is useful for making water pipes, and so copper(II) carbonate is quite unstable and decomposes at a relatively low temperature.

The stability of the metal carbonates can be related to the reactivity series of metals. The higher up the series a metal is, the more reactive the metal is and so the more stable the metal carbonate is.

A list of metals from most reactive and most stable carbonate (potassium) to least reactive and least stable carbonate (platinum).

The stability of the metal carbonates can be measured by heating the carbonate and bubbling the carbon dioxide given off through limewater. The quicker the limewater becomes milky, the greater the rate of decomposition of the carbonate (meaning the carbonate is less stable).

Diagram showing how the stability of the metal carbonates can be measured, in this case by heating copper(II) carbonate and bubbling the carbon dioxide given off through limewater.