Hydrolysis of Halogenoalkanes (Edexcel A Level Chemistry): Revision Note

Author

Richard Boole

Last updated

4 January 2025

Core Practical 4: Investigating Halogenoalkane Hydrolysis

Halogenoalkanes can be hydrolysed with an aqueous solution of sodium hydroxide (NaOH) or potassium hydroxide (KOH)
This reaction is very slow at room temperature, so the reaction mixture is warmed
The rate of this reaction depends on the type of halogen in the halogenoalkane
- The stronger the C-X bond, the slower the rate of the reaction
- In terms of bond enthalpy, C-F > C-Cl > C-Br > C-I
- Fluoroalkanes do not react at all, but iodoalkanes have a very fast rate of reaction

Halogen Compounds Electrophilic Substitution by NaOH, downloadable AS & A Level Chemistry revision notes

The halogen is replaced by the nucleophile, OH^-

This reaction could also be done with water as the nucleophile, but it is very slow
- The hydroxide ion is a better nucleophile than water as it carries a full negative charge
- In water, the oxygen atom only carries a partial charge

Halogen Compounds Nucleophilicity, downloadable AS & A Level Chemistry revision notes

A hydroxide ion is a better nucleophile as it has a full formal negative charge whereas the oxygen atom in water only carries a partial negative charge; this causes the nucleophilic substitution reaction with water to be much slower than the aqueous alkali

Measuring the rate of hydrolysis

Acidified silver nitrate can be used to measure the rate of hydrolysis of halogenoalkanes
Set up three test tubes in a 50 ^oC water bath, with a mixture of ethanol and acidified silver nitrate
Add a few drops of a chloroalkane, bromoalkane and an iodoalkane to each test tube and start a stop watch
Time how long it takes for the precipitates to form
The precipitate will form as the reaction progresses and the halide ions are formed
A white precipitate will form from the chloroalkane, a cream precipitate will form from the bromoalkane and a yellow precipitate will form from the iodoalkane
- The yellow precipitate will form the fastest
- This is because the C-I bond has the lowest bond enthalpy, so it is the easiest to break and will cause the I^- ions to form the fastest
- The white precipitate will form the slowest
- This is because the C-Cl bond has the highest bond enthalpy, so it is the hardest to break and will cause the Cl^- ions to form the slowest

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Previous:Determining Enthalpy Change of ReactionNext:Ethanol Oxidation

Hydrolysis of Halogenoalkanes (Edexcel A Level Chemistry): Revision Note

Core Practical 4: Investigating Halogenoalkane Hydrolysis

Measuring the rate of hydrolysis

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