Shapes of molecules

Specification Reference Topic 1, points 1–6

Quick Notes

Electron pairs around a central atom repel and arrange themselves as far apart as possible to minimise repulsion, giving different bonding shapes and arrangements.
Repulsion order: Lone pair–lone pair > lone pair–bond pair > bond pair–bond pair.
The shape of a molecule is determined by the number of bonding and lone pairs around the central atom.
Common shapes and bond angles:
- Linear (180°) – e.g. CO₂
- Bent (104°) – e.g. H₂O
- Trigonal planar (120°) – e.g. BF₃
- Trigonal pyramidal (107°) – e.g. NH₃
- Tetrahedral (109.5°) – e.g. CH₄
- Square planar (90°) – e.g. XeF₄
- Trigonal bipyramidal (90°, 120°, 180°) – e.g. PCl₅
- Octahedral (90°, 180°) – e.g. SF₆

Full Notes

Electron Pair Repulsion Theory

The shape of a molecule can be predicted based on the number of bonds and lone pairs around the central atom. Bonds and lone pairs are considered regions of electron density.

Bonding pairs and lone pairs repel each other due to their negative charge.
To minimise repulsion, electron pairs arrange themselves as far apart as possible.
Repulsion strengths follow this order:

Lone pair–lone pair (LP–LP) repulsion → strongest repulsion
Lone pair–bond pair (LP–BP) repulsion → intermediate repulsion
Bond pair–bond pair (BP–BP) repulsion → weakest repulsion

Lone pairs reduce bond angles by forcing bonding pairs closer together.

Common Molecular Shapes and Bond Angles

Quick Reference Summary Table at Bottom of Page

Linear (180°)

2 bonding pairs, no lone pairs → bonds remain in a straight line.

A-Level Chemistry diagram showing linear shape with 180° bond angle

Trigonal Planar (120°)

3 bonding pairs, no lone pairs → flat triangle arrangement.

Examples: BF₃, NO₃⁻

A-Level Chemistry diagram showing trigonal planar shape with 120° bond angle

Tetrahedral (109.5°)

4 bonding pairs, no lone pairs → 3D tetrahedral shape.

Examples: CH₄, NH₄⁺

A-Level Chemistry diagram showing tetrahedral shape with 109.5° bond angle

Trigonal Pyramidal (107°)

3 bonding pairs, 1 lone pair → bond angle reduced due to lone pair repulsion.

Examples: NH₃, PCl₃

A-Level Chemistry diagram showing trigonal pyramidal shape with 107° bond angle

Bent (104.5°)

2 bonding pairs, 2 lone pairs → bond angle reduced further by two lone pairs.

Examples: H₂O, OF₂

A-Level Chemistry diagram showing bent V-shaped structure with 104.5° bond angle

Trigonal Bipyramidal (90°, 120°, 180°)

5 bonding pairs, no lone pairs → atoms arranged in two layers.

Example: PCl₅

A-Level Chemistry diagram showing trigonal bipyramidal shape with bond angles of 90°, 120°, and 180°

Octahedral (90°, 180°)

6 bonding pairs, no lone pairs → symmetrical 3D shape.

Example: SF₆

A-Level Chemistry diagram showing octahedral shape with 90° and 180° bond angles

Square Planar (90°)

4 bonding pairs, 2 lone pairs → lone pairs opposite, minimising repulsion.

Example: XeF₄

A-Level Chemistry diagram showing square planar structure with 90° bond angles

Effect of Lone Pairs on Bond Angles

Lone pairs repel bonding pairs more than bonding pairs repel each other. This pushes bonding pairs closer together and reduces bond angles.

A-Level Chemistry diagram showing how lone pairs affect bond angles

Lone Pairs Present	Bond Angle Reduction	Example
0	No reduction	CH₄ (109.5°)
1	~2.5° smaller	NH₃ (107°)
2	~5° smaller	H₂O (104.5°)

Molecular Shapes and Bond Angles – Key Examples

Molecule	Electron Pair Geometry	Shape	Bond Angle(s)	Explanation
CO₂	2 bonding pairs	Linear	180°	No lone pairs, equal repulsion between bonds keeps atoms in a straight line
BF₃	3 bonding pairs	Trigonal planar	120°	Bonds spread evenly in one plane with equal repulsion
CH₄	4 bonding pairs	Tetrahedral	109.5°	Four bonds repel equally in 3D space, forming a symmetrical shape
NH₃	3 bonding + 1 lone pair	Pyramidal	107°	Lone pair pushes bonding pairs slightly closer together
H₂O	2 bonding + 2 lone pairs	Non-linear	104.5°	Two lone pairs create even more repulsion, reducing angle further
PF₅	5 bonding pairs	Trigonal bipyramidal	120° (eq), 90° (ax)	Three bonds form a triangle in one plane; two others are perpendicular
SF₆	6 bonding pairs	Octahedral	90°	All 6 electron pairs repel equally, forming a symmetrical 3D shape

Application in Ions and Organic Molecules

The same rules as above apply for polyatomic ions and organic molecules.

For Example:

NH₄⁺ → Tetrahedral (109.5°)
NO₃⁻ → Trigonal Planar (120°)
OH⁻ → Bent (~104.5°)
The central carbon in ethene (C₂H₄) has a trigonal planar geometry around each carbon
In methanol (CH₃OH), the oxygen atom forms a bent shape similar to water due to two lone pairs

Summary

Shape	Bond Angle	Lone Pairs?	Example
Linear	180°	No	CO₂
Trigonal Planar	120°	No	BF₃
Tetrahedral	109.5°	No	CH₄
Trigonal Pyramidal	107°	1	NH₃
Bent (V‑Shaped)	104.5°	2	H₂O
Trigonal Bipyramidal	90° & 120°	No	PCl₅
Seesaw	<90° & <120°	1	SF₄
T‑Shaped	<90°	2	ClF₃
Octahedral	90°	No	SF₆
Square Pyramidal	<90°	1	BrF₅
Square Planar	90°	2	XeF₄

Electron pairs repel and arrange as far apart as possible (VSEPR theory).
Lone pairs repel more strongly than bonding pairs, reducing bond angles.
Common shapes include linear, trigonal planar, tetrahedral, trigonal pyramidal, bent, trigonal bipyramidal, octahedral, and square planar.
These rules apply to both molecules and polyatomic ions.