Acylation (AQA A Level Chemistry)

Revision Note

Author

Stewart Hird

Last updated

26 October 2024

Acyl Groups

Acyl groups

Acyl groups can be built into many molecules using acyl chlorides or acid anhydrides (known as acylating agents)
Acyl chlorides are derivatives of carboxylic acids by substitution of the -OH group by a chlorine atom
- Acyl chlorides are named by identifying the parent hydrocarbon chain and adding the suffix -oyl chloride
- They can also be named by removing the -oic acid from the carboxylic acid and adding -oyl chloride
Acid anhydrides are also derivatives of carboxylic acids formed by substitution of the -OH group by an alkanoate
- Acid anhydrides are named by identifying the parent hydrocarbon chain and adding the suffix -oic anhydride
- They can also be named by removing the -oic acid from the carboxylic acid and adding -oic anyhydride

Ethanoic acid derivatives

Worked Example

Draw the displayed formula for the following:a) butanoyl chlorideb) butanoic anhydride

Answer:

Nucleophilic Addition–Elimination

Acyl chlorides are reactive organic compounds that undergo many reactions such as nucleophilic addition-elimination reactions
In nucleophilic addition-elimination reactions, the nucleophilic addition of a small molecule across the C=O bond takes place followed by elimination of a small molecule
Examples of these nucleophilic addition-elimination reactions include:
- Hydrolysis
- Reaction with alcohols to form esters
- Reaction with ammonia and primary amines to form amides

Hydrolysis

The hydrolysis of acyl chlorides results in the formation of a carboxylic acid and HCl molecule
This is a nucleophilic addition-elimination reaction
- A water molecule adds across the C=O bond
- A hydrochloric acid (HCl) molecule is eliminated
An example is the hydrolysis of propanoyl chloride to form propanoic acid and HCl

Acyl chlorides are hydrolysed to carboxylic acids

Formation of esters

Acyl chlorides can react with alcohols to form esters
The esterification of acyl chlorides is also a nucleophilic addition-elimination reaction
- The alcohol adds across the C=O bond
- A HCl molecule is eliminated

Acyl chlorides undergo esterification with alcohols to form esters

Formation of amides

Acyl chlorides can form amides with primary amines and ammonia
The nitrogen atom in ammonia and primary amine has a lone pair of electrons which can be used to attack the carbonyl carbon atom in the acyl chlorides
The product is an amide (when reacted with ammonia) or N-substituted amide (when reacted with primary amines)
This is also an example of a nucleophilic addition-elimination reaction as
- The amine or ammonia molecule adds across the C=O bond
- A HCl molecule is eliminated

Formation of amide reaction, downloadable AS & A Level Chemistry revision notes

Acyl chlorides undergo reactions with ammonia and primary amines to form amides

Nucleophilic Addition–Elimination Mechanism

Acyl chlorides undergo nucleophilic addition-elimination reactions such as hydrolysis, esterification reactions to form esters, and condensation reactions to form amides
The general mechanism of these nucleophilic addition-elimination reactions involve two steps:
- Step 1 - Addition of a nucleophile across the C=O bond
- Step 2 - Elimination of a small molecule such as HCl or H₂O

Mechanism of hydrolysis of acyl chlorides

In the hydrolysis of acyl chlorides, the water molecule acts as a nucleophile
- Step 1 - Nucleophilic addition; the lone pair on the oxygen atoms carry out an initial attack on the carbonyl carbon
- Step 2 - Elimination; this is followed by the elimination of a hydrochloric acid (HCl) molecule

Carboxylic Acids _ Derivatives - Mechanism Hydrolysis, downloadable AS & A Level Chemistry revision notes

Reaction mechanism of the hydrolysis of acyl chlorides

Formation of esters: reaction mechanism

In the esterification reaction of acyl chlorides, the alcohols act as a nucleophile
- Step 1 - Nucleophilic addition; the lone pair on the oxygen atoms carry out an initial attack on the carbonyl carbon
- Step 2 - Elimination; this is again followed by the elimination of an HCl molecule

Carboxylic Acids _ Derivatives - Mechanism Esterification with Alcohol, downloadable AS & A Level Chemistry revision notes

Reaction mechanism of the esterification of acyl chlorides with alcohols

Formation of amides: reaction mechanism

The nitrogen atom in ammonia and primary amines act as a nucleophile
- Step 1 - Nucleophilic addition; the lone pair on the nitrogen atoms carry out an initial attack on the carbonyl carbon
- Step 2 - Elimination; this is followed by the elimination of an HCl molecule
- Step 3 - Acid-Base reaction; the HCl formed would immediately react with excess ammonia to give ammonium chloride in an acid-base reaction

Formation of amides from acyl chlorides with ammonia 1, downloadable AS & A Level Chemistry revision notes

Reaction mechanism of the formation of amides from acyl chlorides with ammonia

Carboxylic Acids _ Derivatives - Mechanism Condensation with Primary Amines (1), downloadable AS & A Level Chemistry revision notes

Reaction mechanism of the formation of amides from acyl chlorides with primary amines

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Acylation (AQA A Level Chemistry)

Revision Note

Acyl Groups

Acyl groups

Nucleophilic Addition–Elimination

Hydrolysis

Formation of esters

Formation of amides

Nucleophilic Addition–Elimination Mechanism

Mechanism of hydrolysis of acyl chlorides

Formation of esters: reaction mechanism

Formation of amides: reaction mechanism

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Physical Chemistry

Atomic Structure

Fundamental Particles

Mass Number & Isotopes

Time of Flight Mass Spectrometry

Shells & Orbitals

Electron Configuration

Ionisation Energy

Ionisation Energy: Trends & Evidence

Formulae, Equations & Calculations

Relative Atomic Mass & Relative Molecular Mass

Empirical & Molecular Formula

Balanced Equations

Reaction Yields

Atom Economy

Hydrated Salts

The Mole, Avogadro & The Ideal Gas Equation

The Mole & the Avogadro Constant

Reacting Masses

Reacting Volumes

The Ideal Gas Equation

Types of Bonding & Properties

Changes in State: Energy Changes

Ionic Bonding

Covalent Bonding

Dative Covalent Bonding

Dot & Cross Diagrams

Metallic Bonding

Properties of Ionic Compounds

Properties of Covalent Substances

Properties of Metallic Substances

Effects of Structure & Bonding

Molecules: Shapes & Forces

Shapes of Simple Molecules & Ions

Bond Polarity

Types of Forces between Molecules

Effects of Forces Between Molecules

Energetics

Bond Energy

Energy Level Diagrams

Enthalpy Changes

Calorimetry

Hess' Law

Applications of Hess’s Law

Bond Enthalpies

Kinetics

Collision Theory

Measuring Rates of Reaction

Maxwell–Boltzmann Distributions

Effect of Temperature on Reaction Rate

Effect of Concentration & Pressure

Catalysts

Chemical Equilibria, Le Chatelier’s Principle & Kc

Chemical Equilibria

Le Chatelier's Principle

The Equilibrium Constant, Kc

Calculations Involving the Equilibrium Constant

Changes Which Affect the Equilibrium

Oxidation, Reduction & Redox Equations

Oxidation & Reduction

Oxidation States: The Rules

Redox Equations

Inorganic Chemistry

Periodicity

Classification of an Element