3.2.12

Reactions of Benzene

Test yourself on Reactions of Benzene

Test your knowledge with free interactive questions on Seneca — used by over 10 million students.

Electrophilic Substitution of Benzene

Reactions of benzene rings tend to retain the stable ring of delocalised electrons. This is possible in electrophilic substitution - where an electrophile replaces a hydrogen on benzene.

Electrophilic substitution

Electrophilic substitution

  • Benzene rings are electron-rich and so attract electrophiles.
  • Electrophilic substitution reactions can be used to introduce halogens, alkyl, acyl and nitro groups to the benzene ring.
    • These reactions often require a Lewis acid catalyst (e.g. AlCl3, FeBr3).
General mechanism

General mechanism

  • Initial attack is by an electrophile on the electron-rich benzene ring.
  • The attack of the electrophile breaks the delocalised electron system and forms a positively charged intermediate, which has lost its aromaticity (less stable).
  • A hydrogen ion (H+) is then removed from the intermediate to regain the aromaticity.
    • It will be easier to understand this mechanism through the specific examples that we will study next.

Chlorination and Nitration

Two specific examples of electrophilic substitution for benzene is chlorination and nitration. We will study nitration in more depth.

Chlorination

Chlorination

  • One chlorine atom substitutes a hydrogen atom.
    • This is carried out by an electrophilic substitution mechanism similar to the nitration mechanism we will look at next.
Nitration

Nitration

  • In nitration, the electrophile is NO2+.
    • This will substitute in for a hydrogen atom.
  • The reagents and conditions are:
    • HNO3.
    • H2SO4 catalyst.
    • 50oC.
  • The NO2+ is formed from the reaction:
    • HNO3 + 2H2SO4 ⇌ NO2+ + 2HSO4- + H3O+
Mechanism of nitration

Mechanism of nitration

  • Above shows the mechanism for the nitration of benzene.
Nitration in industry

Nitration in industry

  • The nitration reaction is very important in the production of the explosive TNT - 2, 4, 6-trinitrotoluene.
  • Nitration is also important in producing aromatic amines which can be used for the synthesis of dyes.

Friedel-Crafts Acylation

Friedel-Crafts reactions can be alkylation and acylation. We will look at acylation.

Acylation of benzene

Acylation of benzene

  • The acylation of benzene adds an acyl group, (RCO-) to the ring.
  • The reaction involves the transformation of the acyl chloride into an electrophile using an AlCl3 catalyst.
    • RCOCl + AlCl3 → RCO+ + AlCl4-
  • This electrophile can then undergo the usual electrophilic substitution as seen on the next slide.
Friedel-Crafts acylation mechanism

Friedel-Crafts acylation mechanism

  • Above shows the mechanism for the acylation of benzene.
    • Firstly, the attack of the electrophile on the electron-rich benzene ring to form the positive, non-aromatic intermediate.
    • Secondly, the proton is removed. This is done using the AlCl4 to react with this proton to form: HCl + AlCl3.
    • This shows how the catalyst is regenerated too!
Jump to other topics
1

Physical Chemistry

1.1

Atoms, Molecules & Stoichiometry

1.1.1Relative Masses1.1.2The Mole1.1.3Mass Spectrometry1.1.4Empirical & Molecular Formulae1.1.5Balanced Equations1.1.6Molar Volume1.1.7End of Topic Test - Amount of Substance
1.2

Atomic Structure

1.2.1Fundamental Particles1.2.2Isotopes & Mass Number1.2.3Electron Shells, Sub-Shells & Orbitals1.2.4Electron Configuration1.2.5Ionisation Energy1.2.6Factors Affecting Ionisation Energies1.2.7Trends of Ionisation1.2.8Specific Impacts on Ionisation Energies1.2.9Electron Affinity1.2.10End of Topic Test - Atomic Structure1.2.11A-A* (AO2/3) - Atomic Structure
1.3

Chemical Bonding

1.3.1Ionic Bonding1.3.2Covalent & Dative Bonding1.3.3Shapes of Molecules1.3.4Intermolecular Forces1.3.5Intermolecular Forces 21.3.6Electronegativity1.3.7Bond Length, Bond Energy, & Bond Polarity1.3.8Metallic Bonding1.3.9Physical Properties1.3.10End of Topic Test - Bonding1.3.11A-A* (AO2/3) - Bonding
1.4

States of Matter

1.4.1Simple Covalent Molecules1.4.2The Ideal Gas Equation1.4.3States of Matter1.4.4Particle Diagrams1.4.5The Liquid State1.4.6Giant Ionic Lattices1.4.7Giant Metallic Lattices1.4.8Giant Covalent Structures1.4.9Graphene & Fullerene1.4.10Recycling
1.5

Chemical Energetics

1.5.1Calorimetry1.5.2Bond Enthalpies1.5.3Enthalpy Changes1.5.4Hess' Law1.5.5Born-Haber Cycles1.5.6Born-Haber Cycle Calculations1.5.7Entropy1.5.8Free Energy1.5.9End of Topic Test - Energetics
1.6

Electrochemistry

1.6.1Electrochemical Cells1.6.2Electrochemical Series1.6.3Commercial Application1.6.4Nernst Equation1.6.5Redox
1.7

Equilibria

1.7.1Dynamic Equilibrium & Le Chatelier1.7.2Kc1.7.3Kp1.7.4pH1.7.5The Ionic Product of Water1.7.6Weak Acids & Bases1.7.7Introduction to Solubility Equilibria1.7.8Solubility Equilibria Calculations1.7.9Free Energy of Dissolution1.7.10pH and Solubility1.7.11Common-Ion Effect1.7.12End of Topic Test - Kp & Electrochemistry1.7.13A-A* (AO2/3) - Electrochemical Cells
1.8

Partition Coefficient

1.8.1Kpc
1.9

Reaction Kinetics

1.9.1Collision Theory1.9.2Orders, Rate Constants & Equations1.9.3Rate Graphs1.9.4Rate Determining Step1.9.5Maxwell-Boltzmann Distribution1.9.6Catalysts1.9.7Homogeneous Catalysts1.9.8Heterogeneous Catalysts1.9.9End of Topic Test - Kinetics1.9.10End of Topic Test - Rate Equations1.9.11A-A* (AO2/3) - Rate Equations
2

Inorganic Chemistry

2.1

The Periodic Table

2.1.1The Periodic Table2.1.2Trends in the Periodic Table2.1.3End of Topic Test - Periodicity & Trends2.1.4Ceramics2.1.5Period 3 Elements & Oxides2.1.6Period 3 Oxides2.1.7End of Topic Test - Period 3
2.2

Group 2

2.2.1Group 2 Chemistry
2.3

Group 17

2.3.1Introduction to Halogens2.3.2Reactions of Halogens2.3.3Chlorine & Chlorate(I)2.3.4End of Topic Test - Group 172.3.5A-A* (AO2/3) - Periodicity, Group 2 & 17
2.4

Transition Metals

2.4.1General Properties2.4.2Titrations2.4.3Shapes of Complex Ions2.4.4Variable Oxidation States2.4.5Ligands2.4.6Colours of Ions2.4.7Stereoisomerism of Complex Ions2.4.8Cisplatin2.4.9Ligand Substitutions & Kstab2.4.10End of Topic Test - Transition Metals2.4.11A-A* (AO2/3) - Transition Metals
2.5

Nitrogen & Sulfur

2.5.1Nitrogen & Ammonia2.5.2Formulated vs Manure Fertilisers2.5.3Nitrogen Containing Fertilisers2.5.4Fertilizers & Eutrophication2.5.5Common Atmospheric Pollutants & Their Properties2.5.6Catalytic Converters2.5.7Atmospheric Oxides
3

Organic Chemistry & Analysis

3.1

Introduction to Organic Chemistry

3.1.1Naming Conventions3.1.2Mechanism3.1.3Isomerism3.1.4End of Topic Test - Introduction to Organic Chem
3.2

Hydrocarbons

3.2.1Fractional Distillation3.2.2Cracking3.2.3Combustion3.2.4Chlorination3.2.5End of Topic Test - Alkanes3.2.6Introduction to Alkenes3.2.7Reactions of Alkenes3.2.8Polymerisation Reactions3.2.9End of Topic Test - Alkenes3.2.10Arenes3.2.11Evidence for Structure of Arenes3.2.12Reactions of Benzene3.2.13End of Topic Test -Arenes
3.3

Halogen Derivatives

3.3.1Properties of Haloalkanes3.3.2Substitution Reactions of Haloalkanes3.3.3Environmental Impacts of Haloalkanes3.3.4End of Topic Test - Halogenoalkanes
3.4

Hydroxy Compounds

3.4.1Types of Alcohol3.4.2Oxidation 13.4.3Oxidation 23.4.4Elimination3.4.5Acids & Esters3.4.6Acyl Chlorides & Acylation3.4.7Phenols & Their Reactions3.4.8End of Topic Test - Alcohols
3.5

Carbonyl Compounds

3.5.1Carbonyls3.5.2Hydrogen Bonding & Carbonyls3.5.3Aldehydes & Ketones3.5.4Tri-Iodomethane Reaction3.5.5End of Topic Test -Carbonyls
3.6

Carboxylic Acids & Derivatives

3.6.1Properties of Carboxylic Acids3.6.2Esters3.6.3Acyl Chlorides3.6.4End of Topic Test - Carboxylic Acids
3.7

Nitrogen Compounds

3.7.1Nature & Preparation of Amines3.7.2Basicity & Nucleophilicity3.7.3Amides3.7.4Reactions of Amino Acids3.7.5Amino Acids
3.8

Polymerisation

3.8.1Properties of Addition Polymers3.8.2Condensation Polymerisation3.8.3Effects of Side-Chains on Polymers3.8.4Hydrolysis of Ester & Amide Groups3.8.5Proteins3.8.6DNA3.8.7Adhesive & Conducting Polymers3.8.8End of Topic Test - Amines & Proteins
3.9

Analytical Techniques

3.9.1Chromatography3.9.2High-Performance Liquid Chromatography3.9.3Gas Chromatography3.9.4IR Spectroscopy3.9.5Uses of IR Spectroscopy3.9.6Mass Spectrometry3.9.7Mass Spectrometry Analysis3.9.8Nuclear Magnetic Resonance3.9.9Carbon-13 NMR3.9.10Proton NMR I3.9.11Proton NMR II3.9.12End of Topic Test - Analytical Techniques3.9.13A-A* (AO2/3) - Analytical Techniques
3.10

Organic Synthesis

3.10.1Chirality & Drug Synthesis3.10.2Organic Synthesis3.10.3Examples of Synthetic Routes3.10.4End of Topic Test - Organic Synthesis

Practice questions on Reactions of Benzene

Can you answer these? Test yourself with free interactive practice on Seneca — used by over 10 million students.

  1. 1
    What's it common for electrophilic substitution reactions at benzene to include?Multiple choice
  2. 2
    In electrophilic substitution, what is lost to regain aromaticity?Multiple choice
  3. 3
    The conditions for nitration are:Fill in the list
  4. 4
    What is the overall charge of the intermediate in nitration?Multiple choice
  5. 5
    The nitration of benzene is important for:Fill in the list
Answer all questions on Reactions of Benzene

Unlock your full potential with Seneca Premium

  • Unlimited access to 10,000+ open-ended exam questions

  • Mini-mock exams based on your study history

  • Unlock 800+ premium courses & e-books

Get started with Seneca Premium

Evidence for Structure of Arenes

End of Topic Test -Arenes