Instead of transferring electrons (as in ionic bonding), non-metals SHARE pairs of electrons.
Each shared pair of electrons counts as ONE COVALENT BOND.
Why sharing works:
Each atom counts the shared electrons as part of its OWN outer shell.
Both atoms achieve full outer shells β without either losing electrons entirely.
The shared electrons are attracted to BOTH nuclei β this attraction holds the atoms together.
Covalent bonds are STRONG β a lot of energy is needed to break an individual covalent bond within a molecule.
Examples of Covalent Molecules
HYDROGEN (Hβ):
Each H has 1 electron β needs 1 more for a full shell (2 electrons).
Two H atoms share 1 pair of electrons β single covalent bond β each H now 'has' 2 electrons. β
WATER (HβO):
O has 6 outer electrons β needs 2 more. H has 1 β needs 1 more.
O forms 2 covalent bonds, one with each H atom.
O now has 8 outer electrons (full). Each H has 2 (full). β
AMMONIA (NHβ):
N has 5 outer electrons β needs 3 more.
N forms 3 single covalent bonds with 3 H atoms.
METHANE (CHβ):
C has 4 outer electrons β needs 4 more.
C forms 4 single covalent bonds with 4 H atoms.
OXYGEN (Oβ):
Each O has 6 outer electrons β needs 2 more.
Two O atoms share 2 pairs of electrons β DOUBLE covalent bond.
NITROGEN (Nβ):
Each N has 5 outer electrons β needs 3 more.
Two N atoms share 3 pairs β TRIPLE covalent bond. Nβ is very stable.
Dot-and-Cross Diagrams for Covalent Molecules
DOT-AND-CROSS diagrams show the shared electrons in covalent bonds.
Convention: each pair of electrons in a bond is shown between the two atoms. Lone pairs (non-bonding) are shown on the relevant atom.
Hβ: H Γ H (one shared pair between the two H atoms β single bond)
HβO:
HβOβH with 2 lone pairs on O.
The 2 bonding pairs give O its full 8, and each H its full 2.
CHβ (methane):
4 H atoms arranged around central C.
4 single bonds β C has 8 electrons in outer shell. Each H has 2.
COβ:
O=C=O β two double bonds.
C has 8 outer electrons (two sets of 2 shared). Each O also has 8.
The key rule: every atom in a correctly drawn dot-and-cross diagram should have a FULL OUTER SHELL.
β οΈ Common Mistake
Covalent bonds are STRONG β but simple molecular substances have LOW melting points because the FORCES BETWEEN molecules (intermolecular forces) are WEAK. The covalent bond is within the molecule; melting involves separating molecules from each other (overcoming intermolecular forces), not breaking the bonds within them.
π Key Note
Covalent bonding: non-metals share electron pairs. Each shared pair = one covalent bond. Both atoms achieve full outer shells. Single bond: 1 shared pair. Double bond: 2 shared pairs. Covalent bonds within molecules are STRONG. Intermolecular forces between molecules are WEAK β low melting points.
π― Matching Activity β Match the Molecule to its Bonding
Match each molecule to how many covalent bonds it contains. β drag the symbols on the right to match the component names on the left.
Hβ
Drop here
HβO
Drop here
CHβ
Drop here
Oβ
Drop here
Nβ
Drop here
2 single covalent bonds β O forms 2 bonds with 2 H atoms
1 single covalent bond β 1 shared pair between 2 H atoms
4 single covalent bonds β C forms 4 bonds with 4 H atoms
1 double covalent bond β 2 shared pairs between 2 O atoms
1 triple covalent bond β 3 shared pairs between 2 N atoms
π― Test Yourself
Question 1 of 2
1. Carbon (Group 4) bonds with hydrogen (Group 1) to form methane (CHβ). How many covalent bonds does carbon form?
2. Why does oxygen exist as Oβ rather than individual O atoms?
β How Well Do You Understand This Topic?
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