Intermolecular Forces (OCR AS Chemistry)

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Philippa Platt

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Intermolecular Forces

Intramolecular forces

  • Intramolecular forces are forces within a molecule and are usually covalent bonds
  • Covalent bonds are formed when the outer electrons of two atoms are shared
  • Single, double, triple and co-ordinate bonds are all types of intramolecular forces

Chemical Bonding Inter and Intramolecular Forces, downloadable AS & A Level Chemistry revision notes

Intermolecular forces

  • Molecules also contain weaker intermolecular forces which are forces between the molecules
  • There are three types of intermolecular forces:
    • Induced dipole – dipole forces are also called London dispersion forces or van der Waals’ forces 
    • Permanent dipole – dipole forces (also called van der Waals’ forces) are the attractive forces between two neighbouring molecules with a permanent dipole
    • Hydrogen Bonding are a special type of permanent dipole - permanent dipole forces
    • Intramolecular forces are stronger than intermolecular forces
      • For example, a hydrogen bond is about one tenth the strength of a covalent bond

Induced dipole-dipole forces:

  • Induced dipole - dipole forces exist between all atoms or molecules
    • They are also known as van der Waals’ forces or London dispersion forcesChemical Bonding Intermolecular Forces (2), downloadable AS & A Level Chemistry revision notes

  • The electron charge cloud in non-polar molecules or atoms are constantly moving
  • During this movement, the electron charge cloud can be more on one side of the atom or molecule than the other
  • This causes a temporary dipole to arise
  • This temporary dipole can induce a dipole on neighbouring molecules
  • When this happens, the δ+ end of the dipole in one molecule and the δ- end of the dipole in a neighbouring molecule are attracted towards each other
  • Because the electron clouds are moving constantly, the dipoles are only temporary
  • Therefore the greater the number of electrons the molecule has or the greater the relative molecular mass, the stronger the induced dipole-dipole forces
    • For example, pentane, C5H12 has a higher boiling point than propane, C3H8 

Permanent dipole - permanent dipole forces:

  • Polar molecules have permanent dipoles
  • The molecule will always have a negatively and positively charged end

Chemical Bonding Permanent Dipole - Permanent Dipole, downloadable AS & A Level Chemistry revision notes

  • Forces between two molecules that have permanent dipoles are called permanent dipole - dipole forces 
  • The δ+ end of the dipole in one molecule and the δ- end of the dipole in a neighbouring molecule are attracted towards each other

Relative strength

  • For small molecules with the same number of electrons, permanent dipoles are stronger than induced dipoles
    • Butane and propanone have the same number of electrons
    • Butane is a nonpolar molecule and will have induced dipole forces
    • Propanone is a polar molecule and will have permanent dipole forces
    • Therefore, more energy is required to break the intermolecular forces between propanone molecules than between butane molecules
    • So, propanone has a higher boiling point than butane

Chemical Bonding Pd - Pd vs Id - Id, downloadable AS & A Level Chemistry revision notes

Pd-pd forces are stronger than id-id forces in smaller molecules with an equal number of electrons

Hydrogen Bonding & Water

Hydrogen bonding

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

  • For hydrogen bonding to take place the following is needed:
    • A species which has an O, N or F (very electronegative) atom bonded to a hydrogen

  • When hydrogen is covalently bonded to an O, N or F, the bond becomes 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
  • For example, in water
    • Water can form two hydrogen bonds, because the O has two lone pairs

Chemical Bonding Water H-Bonds, downloadable AS & A Level Chemistry revision notes

Properties of water

  • Hydrogen bonding in water, causes it to have anomalous properties such as high melting and boiling points, high surface tension and anomalous density of ice compared to water

High melting & boiling points

  • Water has high melting and boiling points which is caused by the strong intermolecular forces of hydrogen bonding between the molecules
  • In ice (solid H2O) and water (liquid H2O) the molecules are tightly held together by hydrogen bonds
  • A lot of energy is therefore required to break the water molecules apart and melt or boil them

 Chemical Bonding Melting and Boiling Points of Water, downloadable AS & A Level Chemistry revision notes

Hydrogen bonds are strong intermolecular forces which are difficult to break causing water to have high melting and boiling points

Effects of Intermolecular Forces

Properties of Molecular substances 


Ice 

  • Solids are denser than their liquids as the particles in solids are more closely packed together than in their liquid state
  • In ice however, the water molecules are packed in a 3D hydrogen-bonded network in a rigid lattice
  • Each oxygen atom is surrounded by hydrogen atoms
  • This way of packing the molecules in a solid and the relatively long bond lengths of the hydrogen bonds means that the water molecules are slightly further apart than in the liquid form
  • Therefore, ice has a lower density than liquid water

Chemical Bonding Density Water, downloadable AS & A Level Chemistry revision notes

The ‘more open’ structure of molecules in ice causes it to have a lower density than liquid water



Iodine

  • The molecular lattice of iodine consists of a neat arrangement of molecules in the crystal lattice which is held together by the weak intermolecular forces 
  • Being a non-polar molecule, the weak intermolecular bonding is due to instantaneous dipole - induced dipole interactions (the weakest of the van der Waals’ forces)
  • Iodine tends to sublime at temperatures approaching 114 oC due to weak intermolecular force
    • A purple vapour is observed when iodine sublimes

2-5-3-crystalline-structure-of-iodine

Crystalline structure of Iodine

Solubility

  • The general principle is that 'like dissolves like' so non-polar substances mostly dissolve in non-polar solvents, like hydrocarbons and they form dispersion forces between the solvent and the solute
  • Polar covalent substances generally dissolve in polar solvents as a result of dipole-dipole interactions or the formation of hydrogen bonds between the solute and the solvent
  • A good example of this is seen in organic molecules such as alcohols and water:

Hydrogen bonds between ethanol and water, downloadable IB Chemistry revision notes

Hydrogen bonds form between ethanol and water

  • As covalent molecules become larger their solubility can decrease as the polar part of the molecule is only a smaller part of the overall structure
    • This effect is seen in alcohols for example where ethanol, C2H5OH, is readily soluble but hexanol, C6H13OH, is not

  • Polar covalent substances are unable to dissolve well in non-polar solvents as their dipole-dipole attractions are unable to interact well with the solvent
  • Giant covalent substances generally don't dissolve in any solvents as the energy needed to overcome the strong covalent bonds in the lattice structures is too great

Conductivity

  • As covalent substances do not contain any freely moving charged particles, they are unable to conduct electricity in either the solid or liquid state
  • However, under certain conditions some polar covalent molecules can ionise and will conduct electricity
  • Some giant covalent structures are capable of conducting electricity due to delocalised electrons

Comparing the Properties of Covalent Compounds Table

Comparing the properties of covalent compounds table, downloadable IB Chemistry revision notes

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Philippa Platt

Author: Philippa Platt

Expertise: Chemistry

Philippa has worked as a GCSE and A level chemistry teacher and tutor for over thirteen years. She studied chemistry and sport science at Loughborough University graduating in 2007 having also completed her PGCE in science. Throughout her time as a teacher she was incharge of a boarding house for five years and coached many teams in a variety of sports. When not producing resources with the chemistry team, Philippa enjoys being active outside with her young family and is a very keen gardener.