Intermolecular forces and physical properties

The big idea: Inside a molecule, atoms are held by strong covalent bonds. But molecules are also pulled towards each other by much weaker forces called intermolecular forces (IMFs).

It is these IMFs — not the covalent bonds — that you must overcome to melt or boil a molecular substance. So IMFs set the boiling point: stronger IMFs → more energy needed → higher boiling point.

Two different forces — don't mix them up: - Covalent bond (intramolecular) — holds atoms together inside a molecule. Strong. - Intermolecular force (between molecules) — pulls separate molecules towards each other. Much weaker.

Boiling water separates the H₂O molecules from each other — it does not break the O–H covalent bonds.

There are three types of intermolecular force. The order of increasing strength is the one you must know:

London (dispersion) < dipole–dipole < hydrogen bonding.

London (dispersion) forces: Present between all molecules, and the only force between non-polar molecules.

They arise from temporary, instantaneous dipoles: electrons move at random, so at any instant a molecule is slightly uneven, inducing a dipole in its neighbour.

More electrons → larger, more polarisable molecule → stronger London forces. This is why they get stronger down a group and as molecules get bigger.

Dipole–dipole forces: Act between polar molecules, which have a permanent dipole (a δ+ end and a δ− end from an electronegativity difference).

The δ+ end of one molecule is attracted to the δ− end of the next. For molecules of similar size, a polar molecule boils higher than a non-polar one.

Hydrogen bonding — the strongest: A special, extra-strong dipole–dipole force. It needs hydrogen bonded directly to N, O or F (the three most electronegative atoms).

The very δ+ hydrogen is strongly attracted to a lone pair on the N, O or F of a neighbouring molecule.

Memory hook: hydrogen bonding only happens with N, O, F — 'H bonds to NOF'.

Almost every exam question here is the same skill: 'explain why X has a higher/lower boiling point than Y' — by comparing their intermolecular forces. There are two classic patterns.

Pattern 1 — boiling point rises down a group / with molecular size: Compare the noble gases or the halogens: boiling point rises as you go down.

Larger molecules have more electrons, so their London (dispersion) forces are stronger → more energy is needed to separate them → higher boiling point. The same logic explains why bp rises along an alkane or alkene series (C₂ < C₃ < C₄ …).

Pattern 2 — anomalously high boiling points (NH₃, H₂O, HF): NH_{3}, H_{2}O and HF boil far higher than their group neighbours (e.g. PH₃, H₂S, HCl), even though they are smaller.

The reason is hydrogen bonding — the strongest IMF — because each has H bonded to N, O or F. PH₃ has only weak London/dipole–dipole forces, so it boils far lower than NH₃.

How this is tested: S2.2.5 is one of the most reliable Paper 2 explain questions, plus a Paper 1A 'name/identify the force' MCQ.

The standard ask is 'explain the boiling-point trend / difference in terms of intermolecular forces'. To score, you must: (1) name the IMF in each substance, (2) say which is stronger (and why — e.g. more electrons, or H–N/O/F present), and (3) link that to the energy needed and the boiling point.

The mark students lose: Never say boiling 'breaks the covalent bonds' or 'breaks the molecules apart'. Boiling only separates the molecules by overcoming the intermolecular forces — the covalent bonds stay intact. Saying 'breaks bonds' loses the mark.