Bond Energy Calculations (WJEC GCSE Chemistry: Combined Science)

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Bond Breaking & Bond Forming

  • Whether a reaction is endothermic or exothermic depends on the difference between the energy needed to break existing bonds and the energy released when the new bonds are formed
  • Bond breaking is always an endothermic process as energy needs to be taken in from the surroundings to break the chemical bonds
  • Bond making is always an exothermic process as energy is transferred to the surroundings as the new bond is formed

Exothermic reactions

  • If more energy is released than is absorbed, then the reaction is exothermic
  • More energy is released when new bonds are formed than energy required to break the bonds in the reactants
  • The change in energy is negative since the products have less energy than the reactants
  • Therefore, an exothermic reaction has a negative value
    • This can be shown in energy profiles and calculations 

The process of bond making

Bond making exothermic reaction, IGCSE & GCSE Chemistry revision notes

Making new chemical bonds releases energy which radiates outwards from the reaction to the surroundings in the form of heat

Endothermic reactions

  • If more energy is absorbed than released, then the reaction is endothermic
  • More energy is absorbed when breaking bonds than energy released when making new bonds 
  • The change in energy is positive since the products have more energy than the reactants
  • Therefore, an endothermic reaction has a positive value
    • This can be shown in energy profiles and calculations 

The bond breaking process

Bond breaking endothermic reaction, IGCSE & GCSE Chemistry revision notes

Breaking chemical bonds requires energy which is taken in from the surroundings in the form of heat

Energy of reaction calculations

  • Each chemical bond has specific bond energy associated with it
  • This is the amount of energy required to break the bond or the amount of energy given out when the bond is formed
  • This energy can be used to calculate how much heat would be released or absorbed in a reaction
  • To do this it is necessary to know the bonds present in both the reactants and products

Method

  • Write a balanced equation if none is present already
    • Optional - draw the displayed formula to identify the type and number of bonds more easily
  • Add together all the bond energies for all the bonds in the reactants – this is the ‘energy in’
  • Add together the bond energies for all the bonds in the products – this is the ‘energy out’
  • Calculate the energy change using:

Energy change = Energy taken in - Energy given out

Worked example

Bond energy calculation example 1:

Hydrogen and chlorine react to form hydrogen chloride gas:

H–H  + Cl–Cl ⟶ H–Cl   H–Cl

The bond energies are given in the table below.

Bond Energy (kJ)
H–H 436
Cl–Cl 242
H–Cl 431

 

Calculate the overall energy change for this reaction and use this value to explain whether the reaction is exothermic or endothermic.

Answer:

  • Calculate the energy in
    • 436 + 242 = 678 (kJ)
  • Calculate the energy out
    • 2 x 431 = 862 (kJ)
  • Calculate the energy change
    • 678 - 862 = –184 (kJ)
  • Since the energy change is a negative number, energy is being released (to the surroundings)
    • Therefore, the reaction is exothermic

Worked example

Bond energy calculation example 2:

Hydrogen reacts with iodine to form hydrogen iodide.

H2  + I2  ⟶ 2HI

The relevant bond energies are shown in the table below.

Bond Energy (kJ)
H–I 366 > 295
H–H 436
I–I 151

 

Calculate the overall energy change for this reaction and use this value to explain why the reaction is endothermic.

Answer:

  • Calculate the energy in
    • 436 + 151 = 587 (kJ)
  • Calculate the energy out
    • 2 x 295 = 590 (kJ)
  • Calculate the energy change
    • 587 - 590 = -3 (kJ)
  • The reaction is exothermic because:
    • More energy is released than taken in 

Worked example

Higher Tier

Hydrogen bromide decomposes to form hydrogen and bromine:

2HBr  H2  + Br2

The overall energy change for this reaction is +103 kJ.

The relevant bond energies are shown in the table below.

Bond Energy (kJ)
H–Br 366
Br–Br  
H–H 436

 

Calculate the bond energy of the Br–Br bond.

Answer:

  • Calculate the energy in
    • 2 x 366 = 732 (kJ)
  • State the energy out
    • 436 + Br–Br 
  • Overall energy change = energy in - energy out
    • +103 = 732 - (436 + Br–Br)
    • +103 = 732 - 436 - Br–Br
  • Calculate the bond energy of the Br–Br bond
    • Br–Br = 732 - 436 - 103
    • Br–Br = +193 (kJ)

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Richard

Author: Richard

Expertise: Chemistry

Richard has taught Chemistry for over 15 years as well as working as a science tutor, examiner, content creator and author. He wasn’t the greatest at exams and only discovered how to revise in his final year at university. That knowledge made him want to help students learn how to revise, challenge them to think about what they actually know and hopefully succeed; so here he is, happily, at SME.