Syllabus Edition

First teaching 2023

First exams 2025

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Intermolecular Forces (HL IB Chemistry)

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Chemistry

Intermolecular Forces

  • There are no covalent bonds between molecules in molecular covalent compounds. There are, however, forces of attraction between these molecules, and it is these which must be overcome when the substance is melted and boiled
  • These forces are known as intermolecular forces
  • There are three main types of intermolecular forces:
    • London(dispersion) forces
    • Dipole-dipole attraction
    • Hydrogen bonding

London (dispersion) forces

  • The electrons in atoms are not static; they are in a state of constant motion
    • It is therefore likely that at any given time the distribution of electrons will not be exactly symmetrical - there is likely to be a slight surplus of electrons on one side of the atoms

Diagram to show how London (dispersion) forces arise

London dispersion forces

London (Dispersion) forces

  • This is known as a temporary dipole
    • It lasts for a very short time as the electrons are constantly moving
    • Temporary dipoles are constantly appearing and disappearing

  • Consider now an adjacent atom. The electrons on this atom are repelled by the negative part of the dipole and attracted to the positive part and move accordingly
  • This is a temporary induced dipole
    • There is a resulting attraction between the two atoms, and this known as London (dispersion) forces, after the German chemist, Fritz London

  • London (dispersion) forces are present between all atoms and molecules, although they can be very weak
    • They are the reason all compounds can be liquefied and solidified
    • London (dispersion) forces tend to have strengths between 1 kJmol-1 and 50 kJmol-1.

  • The strength of the London( dispersion) forces in between molecules depends on two factors:
    • the number of electrons in the molecule
    • Surface area of the molecules

Number of electrons

  • The greater the number of electrons in a molecule, the greater the likelihood of a distortion and thus the greater the frequency and magnitude of the temporary dipoles
  • The dispersion forces between the molecules are stronger and the melting and boiling points are larger
  • The enthalpies of vaporisation and boiling points of the noble gases illustrate this factor:

Graph to show the effect of number of electrons on enthalpy of vaporisation and boiling point

the effect of number of electrons on london dispersion forces

As the number of electrons increases more energy is needed to overcome the forces of attraction between the noble gases atoms

Surface area

  • The larger the surface area of a molecule, the more contact it will have with adjacent molecules
  • The greater its ability to induce a dipole in an adjacent molecule, the greater the London (dispersion) forces and the higher the melting and boiling points
  • This point can be illustrated by comparing different isomers containing the same number of electrons:

Diagram to show the effect of surface area on intermolecular forces

effect of surface area on london dispersion forces

Boiling points of molecules with the same numbers of electrons but different surface areas

Dipole-dipole attractions

  • Temporary dipoles exist in all molecules, but in some molecules there is also a permanent dipole
  • In addition to the London (dispersion) forces caused by temporary dipoles, molecules with permanent dipoles are also attracted to each other by permanent dipole-dipole bonding

Diagram to show permanent dipole-dipole interactions

permanent-dipole-permanent-dipole

The delta negative end of one polar molecule will be attracted towards the delta positive end of a neighbouring polar molecule

  • This is an attraction between a permanent dipole on one molecule and a permanent dipole on another.
  • Dipole-dipole bonding usually results in the boiling points of the compounds being slightly higher than expected from temporary dipoles alone
    • it slightly increases the strength of the intermolecular attractions

  • The effect of dipole-dipole bonding can be seen by comparing the melting and boiling points of different substances which should have London(dispersion) forces of similar strength

Comparing butane and propanone

  • For small molecules with the same number of electrons, dipole-dipole attractions are stronger than dispersion forces
    • Butane and propanone have the same number of electrons
    • Butane is a nonpolar molecule and will have only dispersion forces
    • Propanone is a polar molecule and will have dipole-dipole attractions and dispersion forces
    • Therefore, more energy is required to break the intermolecular forces between propanone molecules than between butane molecules
    • The result is that propanone has a higher boiling point than butane 

Diagram to show the structures of butane and propanone

butane-and-propanone

Comparing substances with permanent and temporary dipoles in smaller molecules with an equal number of electrons

Dipole-induced dipole attraction

  • Some mixtures might contain both polar and nonpolar molecules, for example HCl and Cl2
  • The permanent dipole of a polar molecule an cause a temporary separation of charge on a non-polar molecule 
  • This force is called dipole-induced dipole attraction 
  • This force acts in addition to the London dispersion forces that occur between nonpolar molecules and the dipole-dipole forces between polar molecules 

Diagram to show dipole-induced dipole attraction

Diagram showing the formation of a dipole-induced dipole attraction between HCl and Cl2 The polar HCl molecule causes a separation of charge on the nonpolar chlorine molecule 

Hydrogen bonding

  • Hydrogen bonding is the strongest type of intermolecular force
    • Hydrogen bonding is a special type of permanent dipole – permanent dipole bonding

  • For hydrogen bonding to take place the following is needed:
    • A species which has an O or N or F (very electronegative) atom with an available lone pair of electrons
    • A hydrogen attached to the O, N or F

  • When hydrogen is covalently bonded to an electronegative atom, such as O, N or F, the bond becomes very highly polarised
  • The H becomes so δ+ charged that it can form a bond with the lone pair of an O, N or F atom in another molecule

Diagram to show polarisation of the H–O/N/F bond

Polarisation in the H-N/O/F bond

The electronegative atoms O or N have a stronger pull on the electrons in the covalent bond with hydrogen, causing the bond to become polarised

  • Hydrogen bonds are represented by dots or dashes between H and the N/O/F element
  • The number of hydrogen bonds depends on:
    • The number of hydrogen atoms attached to O, N or F in the molecule
    • The number of lone pairs on the O, N or F

 Diagram to show hydrogen bonding in ammonia

hydrogen bonding in ammonia

Ammonia can form a maximum of one hydrogen bond per molecule

 

Diagram to show hydrogen bonding in water

hydrogen bonding in water

Water can form a maximum of two hydrogen bonds per molecule

Van der Waals' forces

  • The term Van der Waal's forces is used to include:
    • London dispersion forces
    • Dipole-induced dipole attractions
    • Dipole-dipole attractions
  • These forces occur between molecules (intermolecularly), as well within a molecule (intramolecularly)

Diagram to show the difference between intermolecular and intramolecular forces

difference between intermolecular and intramolecular

The polar covalent bonds between O and H atoms are intramolecular forces and the permanent dipole – permanent dipole forces between the molecules are intermolecular forces 

Exam Tip

The term “London (dispersion) forces” refers to instantaneous induced dipole induced dipole forces that exist between any atoms or groups of atoms and should be used for non-polar species. 

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Alexandra

Author: Alexandra

Alex studied Biochemistry at Newcastle University before embarking upon a career in teaching. With nearly 10 years of teaching experience, Alex has had several roles including Chemistry/Science Teacher, Head of Science and Examiner for AQA and Edexcel. Alex’s passion for creating engaging content that enables students to succeed in exams drove her to pursue a career outside of the classroom at SME.