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REVISION NOTES

IGCSE Edexcel Chemistry

Home / Resources / IGCSE / Chemistry / Revision Notes / 3.3 Reversible Reactions and Equilibria
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3.3 Reversible Reactions and Equilibria

3.3.1 Know that some reactions are reversible and this is indicated by the symbol ⇌ in equations

COMPLETE REACTION

  • Some reactions go to completion
    Meaning that: when all reactants are used up to form products, the reaction stops
  • Indicated by the “→” in the chemical equation
  • For example: 2H2O2 → 2H2O + O2

REVERSIBLE REACTION

  • Some reactions are reversible
  • Meaning that: products can react or decompose and form reactants again
    Reaction occurs in both directions
    • Forward reaction (reactant → product)
    • Reverse reaction (product → reactant)
  • Indicated by the “⇌” in the chemical equation
  • For example: CuSO4・5H2O ⇌ CuSO4  + 5H2O

3.3.2 Describe reversible reactions such as the dehydration of hydrated copper(II) sulfate and the effect of heat on ammonium chloride

Examples of Reversible Reaction

  • Dehydration of hydrated copper(II) sulphate
  • Thermal decomposition of ammonium chloride

Example 1 Dehydration of Hydrated Copper(II) Sulphate 

  • When hydrated CuSO4・5H2O crystals are heated in a test tube
    • Water is removed
    • Blue crystals turn into white powder
  • When anhydrous CuSO4 is added to water
    • White powder turns blue
    • Heat is given off (reaction is exothermic)

CuSO4・5H2O (s) ⇌ CuSO4 (s) + 5H2O (l)

EXAMPLE 2 THERMAL DECOMPOSITION OF AMMONIUM CHLORIDE

  • Heating ammonium chloride produces ammonia and hydrogen chloride gases

NH4Cl (s) → NH3 (g) + HCl (g)

  • As the hot gases cool down they recombine to form solid ammonium chloride

NH3 (g) + HCl (g) → NH4Cl (s)

ammonium chloride ⇌ ammonia + hydrogen chloride

NH4Cl (s) ⇌ NH3 (g) + HCl (g)

3.3.3C Know that a reversible reaction can reach dynamic equilibrium in a sealed container

DYNAMIC EQUILIBRIUM

  • Dynamic equilibrium can be reached when a reversible reaction is taken place in a closed system
  • None of the participating chemical substances are able to leave the container
edexcel_igcse_chemistry_topic 20_reversible reactions and equilibria_002_closed system requirement for reversible reactions

3.3.4C Know that the characteristics of a reaction at dynamic equilibrium are:

  • The forward and reverse reactions occur at the same rate
  • The concentrations of reactants and products remain constant.

When a reaction is at dynamic equilibrium:

  • Both forward and reverse reactions are occuring at the same rate
  • Therefore, the net change of the system is constant, and the concentrations of reactants and products respectively remain constant
  • Dynamic equilibrium does not mean the concentrations of reactants and products are the same
  • Dynamic equilibrium does not mean the reaction stops, both forward and reverse reactions are still happening.
edexcel_igcse_chemistry_topic 20_reversible reactions and equilibria_003_rate of forwards and backwards reaction equal at equilibrium graph

3.3.5C Understand why a catalyst does not affect the position of equilibrium in a reversible reaction

Presence of catalyst does not affect the position of equilibrium

  • Catalyst increases the rate of reaction
    • In this case, it increases the rate of both forward and reverse reactions
  • It does not change the concentration of reactants and products at equilibrium
  • Position of equilibrium is not affected
edexcel_igcse_chemistry_topic 20_reversible reactions and equilibria_004_catalyst effect on rate of reaction

3.3.6C Know the effect of changing either temperature or pressure on the position of equilibrium in a reversible reaction:

  • An increase (or decrease) in temperature shifts the position of equilibrium in the direction of the endothermic (or exothermic) reaction
  • An increase (or decrease) in pressure shifts the position of equilibrium in the direction that produces fewer (or more) moles of gas

References to Le Chatelier’s principle are not required

When the condition of a system at equilibrium is changed:
  • The system would respond to oppose the change
  • This is known as Le Chatelier’s principle (not required)
  • Factors to be discussed:
    • Temperature
    • Pressure

Effect of Temperature 

Example

ICl     +     Cl2     ⇌         ICl3

Dark brown                        Yellow 

When the equilibrium mixture is heated, it becomes dark brown in colour. 

HOW DO WE KNOW WHETHER THE BACKWARD REACTION IS EXOTHERMIC OR ENDOTHERMIC?

  • Equilibrium has shifted to the left as the colour dark brown means that more of ICI is produced
  • Increasing temperature moves the equilibrium in the endothermic direction
  • So the backward reaction is endothermic

Effect of Pressure 

Example

2NO2       ⇌         N2O4

       Brown gas            Colourless gas

WHAT IS THE EFFECT OF AN INCREASE IN PRESSURE ON THE POSITION OF EQUILIBRIUM?

  • Number of gas molecules on the left = 2
  • Number of gas molecules on the right =  1
  • An increase in pressure will cause equilibrium to shift in the direction that produces the smaller number of molecules of gas (2 → 1)
  • So equilibrium shifts to the right
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Next

1.1 State of Matter

1.2 Elements, Compounds and Mixtures

1.3 Atomic Structure

1.4 The Periodic Table

1.5 Chemical Formulae, Equations and Calculations

1.6 Ionic Bonding

1.7 Covalent Bonding

1.8 Metallic Bonding

1.9 Electrolysis

2.1 Group 1 (Alkali Metals) – Lithium, Sodium and Potassium

2.2 Group 7 (Halogens) – Chlorine, Bromine and Iodine

2.3 Gases in the Atmosphere

2.4 Reactivity Series

2.5 Extraction and Uses of Metals

2.6 Acids, Alkalis and Titrations

2.7 Acids, Bases and Salt Preparations

2.8 Chemical Tests

3.1 Energetics

3.2 Rates of Reaction

3.3 Reversible Reactions and Equilibria

4.1 Introduction

4.2 Crude Oil

4.3 Alkanes

4.4 Alkenes

4.5 Alcohols

4.6 Carboxylic Acids

4.7 Esters

4.8 Synthetic Polymers

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