Reactions of the Halide Ions (Cambridge (CIE) AS Chemistry)
Revision Note
Halide Ions: Reducing Agents
Halide ions can also act as reducing agents and donate electrons to another atom
The halide ions themselves get oxidised and lose electrons
The reducing power of the halide ions increases going down the group
This trend can be explained by looking at the ionic radii of the halides’ ions
The ionic radii of the halide ions
The diagram shows that going down the group the ionic radii of the halogens increases
Going down the group, the halide ions become larger
The outermost electrons get further away from the nucleus
The outermost electrons also experience more shielding by inner electrons
As a result of this, the outermost electrons are held less tightly to the positively charged nucleus
Therefore, the halide ions lose electrons more easily going down the group and their reducing power increases
Linking the ionic radius to the reducing power of the halide ions
The reducing power of the halide ions increases going down the group
Examiner Tips and Tricks
The ionic radius is a measure of the size of an atom’s ion
Reactions of Halide Ions
Silver ions & ammonia
Halide ions can be identified in an unknown solution by dissolving the solution in nitric acid and then adding a silver nitrate solution followed by ammonia solution
The halide ions will react with the silver nitrate solution as follows:
General equation: AgNO3 (aq) + X– (aq) → AgX (s) + NO3– (aq)
Ionic equation: Ag+ (aq) + X– (aq) → AgX (s)
X- is the halide ion in both equations
If the unknown solution contains halide ions, then a precipitate of the silver halide will be formed (AgX)
Testing for halide ions
A silver halide precipitate is formed upon the addition of silver nitrate solution to halide ion solution
Dilute followed by concentrated ammonia is added to the silver halide solution to identify the halide ion
If the precipitate dissolves in dilute ammonia the unknown halide is chloride
If the precipitate does not dissolve in dilute but in concentrated ammonia the unknown halide is bromide
If the precipitate does not dissolve in dilute or concentrated ammonia the unknown halide is iodide
Adding ammonia after the halide ion test
Silver chloride and silver bromide precipitates dissolve on the addition of ammonia solution whereas silver iodide doesn’t
Reaction of halide ions with silver nitrate & ammonia solutions table
Halide ion | Colour of silver halide precipitate | Effect of adding dilute ammonia solution to the precipitate | Effect of adding concentrated ammonia solution to the precipitate |
|---|---|---|---|
Cl– (aq) | White | Dissolves | Dissolves |
Br– (aq) | Cream | Insoluble | Dissolves |
I– (aq) | Yellow | Insoluble | Insoluble |
Concentrated sulfuric acid
Chloride, bromide and iodide ions react with concentrated sulfuric acid to produce toxic gases
These reactions should therefore be carried out in a fume cupboard
The general reaction of the halide ions with concentrated sulfuric acid is:
General equation: H2SO4 (l) + X– (aq) → HX (g) + HSO4– (aq)
Where X– is the halide ion
Reaction of chloride ions with concentrated sulfuric acid
Concentrated sulfuric acid is dropwise added to sodium chloride crystals to produce hydrogen chloride gas
The hydrogen chloride gas produced is wet, so it can be passed through a conical flask of concentrated sulfuric acid to produce dry hydrogen chloride gas
Apparatus for the reaction of sodium chloride with concentrated sulfuric acid
Sodium chloride reacts with concentrated sulfuric acid to form dense hydrogen chloride gas
The reaction that takes place is:
H2SO4 (l) + NaCl (s) → HCl (g) + NaHSO4 (s)
The HCl gas produced is seen as white fumes
Reaction of bromide ions with concentrated sulfuric acid
The thermal stability of the hydrogen halides decreases down the group
The reaction of sodium bromide and concentrated sulfuric acid is:
H2SO4 (l) + NaBr (s) → HBr (g) + NaHSO4 (s)
The concentrated sulfuric acid oxidises HBr which decomposes into bromine and hydrogen gas and sulfuric acid itself is reduced to sulfur dioxide gas:
2HBr (g) + H2SO4 (l) → Br2 (g) + SO2 (g) + 2H2O (l)
The bromine is seen as a reddish-brown gas
Reaction of iodide ions with concentrated sulfuric acid
The reaction of sodium iodide and concentrated sulfuric acid is:
H2SO4 (l) + NaI (s) → HI (g) + NaHSO4 (s)
Hydrogen iodide decomposes the easiest
Sulfuric acid oxidises the hydrogen iodide to several extents:
The concentrated sulfuric acid oxidises HI and is itself reduced to sulfur dioxide gas:
2HI (g) + H2SO4 (l) → I2 (g) + SO2 (g) + 2H2O (l)
Iodine is seen as a violet/purple vapour
The concentrated sulfuric acid oxidises HI and is itself reduced to sulfur:
6HI (g) + H2SO4 (l) → 3I2 (g) + S (s) + 4H2O (l)
Sulfur is seen as a yellow solid
The concentrated sulfuric acid oxidises HI and is itself reduced to hydrogen sulfide:
8HI (g) + H2SO4 (l) → 4I2 (g) + H2S (s) + 4H2O (l)
Hydrogen sulfide has a strong smell of bad eggs
Halide ion reactions with concentrated sulfuric acid table
Halide ion | Reaction with concentrated sulfuric acid | Observations |
|---|---|---|
Cl– (aq) | H2SO4 (aq) + NaCl (s) → HCl (g) + NaHSO4 (aq) | White fumes of HCl gas |
Br– (aq) | H2SO4 (aq) + NaBr (s) → HBr (g) + NaHSO4 (aq) 2HBr (g) + H2SO4 (l) → Br2 (g) + SO2 (g) + 2H2O (l) | Reddish brown Br2 gas |
I– (aq) | H2SO4 (aq) + NaI (s) → HI (g) + NaHSO4 (aq) H2SO4 (aq) + 2HI (s) → I2 (g) + SO2 (g) + 2H2O (l) H2SO4 (aq) + 6HI (s) → 3I2 (g) + S (s) + 4H2O (l) H2SO4 (aq) + 8HI (s) → 4I2 (g) + H2S (s) + 4H2O (l) |
Violet / purple I2 vapour Yellow solid of S Strong, bad (egg) smell of H2S |
Examiner Tips and Tricks
It gets easier to oxidise the hydrogen halides as you descend Group 17: the halides become stronger reducing agents
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