Giant Molecular Structures

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Chemistry

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10th - 12th Grade

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Hard

Joseph Anderson

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10 Slides • 4 Questions

Giant Molecular Structures

Cambridge AS Level Chemistry

Giant Molecular Structures

Some covalently bonded structures have a three dimensional network of covalent bonds that called giant molecular structures or giant covalent structures.
They have high melting and boiling points because of the large number of strong covalent bonds linking the whole structure.

Giant molecular structures can be elements (e.g. graphite and diamond), and can be a compound, such as silicon oxide.
Diamond and graphite are different forms of the same element. Different crystalline or molecular forms of the same element are called allotropes.

Multiple Choice

Define the term allotropes

Atoms with same proton number but different number of neutrons

Atoms with same proton number but different mass number

Atoms in different arrangement in structure

Atoms in different arrangement and different physical form

Graphite

In graphite, the carbon atoms are arranged in planar layers. Within the layers, the carbon atoms are arranged in hexagons. Each carbon atom is joined to three other carbon atoms by strong covalent bonds.
The fourth electron of each carbon atom occupies a p orbital. These p orbitals overlap sideways. A cloud of delocalised electrons is formed above and below the plane of the carbon rings.
The layers of carbon atoms are kept next to each other by weak van der Waals forces.

Physical properties of graphite

High melting and boiling points: there is strong covalent bonding throughout the layers of carbon atoms. A lot of energy is needed to overcome these strong bonds.
Softness: graphite is easily scratched. The forces between the layers are weak. The layers of graphite can slide over each other when force is applied. The layers readily flakes off. This is why graphite is used in 'pencil leads' and feels slippery.
Good conductor and electricity: when a voltage is applied, the delocalised electrons (mobile electrons) can move along the layers.

Open Ended

Why graphite can conduct electricity?

Type response here

Diamond

In diamond, each carbon atom forms four covalent bonds with other carbon atoms. The carbon atoms are tetrahedrally arranged around each other. The network of carbon atoms extends almost unbroken throughout the whole structure. The regular arrangement of the atoms gives diamond a crystalline structure.

Physical properties of diamond

High melting and boiling points: there is strong covalent bonding throughout the whole structure. A lot of energy is needed to break these bonds and separate the atoms.
Hardness: diamond cannot be scratched easily because it is difficult to break the three-dimensional network of strong covalent bonds.
Does not conduct electricity or heat: each of the four outer electrons on every carbon atom is involved in covalent bonding. This means that there are no free electrons available to carry the electric current.

Multiple Choice

Which answer shows the correct number of C-C covalent bonds in its allotropes?

Diamond 3, Graphite 3

Diamond 4, Graphite 3

Diamond 3, Graphite 4

Diamond 4, Graphite 4

Silicon (IV) oxide, SiO₂

There are several forms of silicon (IV) oxide. The silicon (IV) oxide found in mineral quartz has a structure similar to diamond.

The structure of SiO₂

Each silicon atom is bonded to four oxygen atoms but each oxygen atom is bonded to only two silicon atoms. So the formula for silicon (IV) oxide is SiO₂.

Physical properties of silicon (IV) oxide

Silicon dioxide has properties similar to that of diamond. It forms hard, colourless crystals with high melting and boiling points and it does not conduct electricity.

Sand is largely silicon (IV) oxide.

Multiple Choice

Silicon (IV) oxide has properties that similar to graphite.

TRUE

FALSE

Giant Molecular Structures

Cambridge AS Level Chemistry

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