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ASChemistryCambridge (CIE)Revision Notes19. Nitrogen CompoundsNitriles & HydroxynitrilesNitriles & Hydroxynitriles

Nitriles & Hydroxynitriles (Cambridge (CIE) AS Chemistry): Revision Note

Exam code: 9701

Philippa Platt

Last updated

Production of Nitriles

  • Nitriles are compounds with a -CN functional group

  • They can be prepared from the nucleophilic substitution of halogenoalkanes

Propanenitrile, an example of a nitrile

Structural formula of propane nitrile showing three carbon atoms, one bonded to nitrogen via a triple bond, and six hydrogen atoms.
There are 2 alkyl type carbon atoms and the nitrile carbon for a total of 3 carbon atoms in propanenitrile

Reaction with KCN

  • The nucleophile in this reaction is the cyanide, CN- ion

  • Ethanolic solution of potassium cyanide (KCN in ethanol) is heated under reflux with the halogenoalkane

  • The product is a nitrile

    • If an aqueous solution of potassium cyanide (KCN (aq)) is heated under reflux with the halogenoalkane, an alcohol can be formed instead of the nitrile

The reaction of bromoethane with ethanolic KCN

Chemical reaction showing bromoethane with KCN in ethanol forming propanenitrile and KBr, highlighting a new C–C bond under heat.
Bromoethane reacts with ethanolic potassium cyanide when heated under reflux to form propanenitrile

Examiner Tips and Tricks

The nucleophilic substitution of halogenoalkanes with KCN adds an extra carbon atom to the carbon chain

This reaction can therefore be used by chemists to make a compound with one more carbon atom than the best available organic starting material

Production of Hydroxynitriles

  • Hydroxynitriles are compounds with both a hydroxy (-OH) and cyanide (-CN) functional group

  • They can be prepared from the nucleophilic addition of aldehydes and ketones

 2-hydroxy-2-methylpropanenitrile, an example of a hydroxynitrile compound

Chemical structure of 2-hydroxy-2-methylpropanenitrile, with OH, CH3, and CN groups bonded to a central carbon; numbered 1 to 3 in red.
Hydroxynitriles contain an OH and a CN group, typically attached to the same carbon atom

Reaction with HCN

  • The nucleophilic addition of hydrogen cyanide to carbonyl compounds is a two-step process

  • In step 1, the cyanide ion attacks the carbonyl carbon to form a negatively charged intermediate

  • In step 2, the negatively charged oxygen atom in the reactive intermediate quickly reacts with aqueous H+ (either from HCN, water or dilute acid) to form a 2-hydroxynitrile

Nucleophilic addition of HCN to carbonyl compounds

Diagram showing nucleophilic attack of ethanal by cyanide ions forming reactive intermediate, followed by protonation yielding 2-hydroxypropanenitrile.
The cyanide ion attacks the carbonyl carbon to form a negatively charged intermediate which quickly reacts with a proton to form a 2-hydroxynitrile compound

Examiner Tips and Tricks

The actual negative charge on the cyanide ion is on the carbon atom and not on the nitrogen atom

Hydrolysis of Nitriles

  • Nitriles are hydrolysed by either dilute acid or dilute alkali followed by acidification to give a carboxylic acid

    • Hydrolysis is the breakdown of a compound using water

Hydrolysis of nitriles

  • Nitriles are hydrolysed by either dilute acid or dilute alkali followed by acidification

    • Hydrolysis by dilute acid results in the formation of a carboxylic acid and ammonium salt

    • Hydrolysis by dilute alkali results in the formation of a sodium carboxylate salt and ammonia; Acidification is required to change the carboxylate ion into a carboxylic acid

  • The -CN group at the end of the hydrocarbon chain is converted to a -COOH group

Hydrolysis of nitriles

Flowchart illustrating the acid and alkali hydrolysis of propanenitrile to yield propanoic acid and ammonium chloride or sodium propanoate.
Hydrolysis of nitriles by either dilute acid (1) or dilute alkali and acidification (2) will form a carboxylic acid

Examiner Tips and Tricks

Unlike the formation of nitriles which add an extra carbon atom to the carbon chain, hydrolysis doesn’t change the number of carbon atoms

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    Philippa Platt

    Author: Philippa Platt

    Expertise: Chemistry Content Creator

    Philippa has worked as a GCSE and A level chemistry teacher and tutor for over thirteen years. She studied chemistry and sport science at Loughborough University graduating in 2007 having also completed her PGCE in science. Throughout her time as a teacher she was incharge of a boarding house for five years and coached many teams in a variety of sports. When not producing resources with the chemistry team, Philippa enjoys being active outside with her young family and is a very keen gardener