2.4 Giant Structures
Cards (57)
- Diamond and graphite are allotropes of carbon with giant covalent structures
- Both substances contain only carbon atoms
- Due to differences in bonding arrangements, they are physically completely different
- Giant covalent structures contain billions of non-metal atoms, each joined to adjacent atoms by covalent bonds forming a giant lattice structure
- Diamond:
- Each carbon atom bonds with four other carbons, forming a tetrahedron
- All the covalent bonds are identical, very strong, and there are no intermolecular forces
- Graphite:
- Each carbon atom in graphite is bonded to three others, forming layers of hexagons
- Leaves one free electron per carbon atom which becomes delocalised
- The covalent bonds within the layers are very strong, but the layers are attracted to each other by weak intermolecular forces
- Properties of Diamond:
- Does not conduct electricity
- Has a very high melting point
- Extremely hard and dense
- All the outer shell electrons in carbon are held in the four covalent bonds around each carbon atom, so there are no freely moving charged particles to carry the current, thus it cannot conduct electricity
- The four covalent bonds are very strong and extend in a giant lattice, so a very large amount of heat energy is needed to break the lattice, thus it has a very high melting point
- Diamond's hardness makes it very useful for purposes where extremely tough material is required
- Used in jewellery due to its sparkly appearance and as cutting tools as it is such a hard material
- The cutting edges of discs used to cut bricks and concrete are tipped with diamonds
- Properties of Graphite:
- Each carbon atom is bonded to three others, forming layers of hexagonal-shaped forms
- One free (delocalised) electron exists in between the layers and is free to move through the structure and carry charge, hence graphite can conduct electricity
- The covalent bonds within the layers are very strong but the layers are connected to each other by weak forces only, hence the layers can slide over each other making graphite slippery and smooth
- Conducts electricity
- Is soft and slippery, less dense than diamond
- Used in pencils and as an industrial lubricant, in engines and in locks
- Also used to make non-reactive electrodes for electrolysis
- Structure of Silicon (IV) Oxide
- Silicon (IV) oxide (also known as silicon dioxide or silica) is a macromolecular compound
- Occurs naturally as sand and quartz
- Each oxygen atom forms covalent bonds with 2 silicon atoms, and each silicon atom in turn forms covalent bonds with 4 oxygen atoms
- A tetrahedron is formed with one silicon atom and four oxygen atoms, similar to diamond
- Diagram showing the structure of SiO2 with the silicon atoms in blue and the oxygen atoms in red
- Comparing Diamond & Silicon (IV) Oxide
- SiO2 has lots of very strong covalent bonds and no intermolecular forces, so it has similar properties to diamond
- Very hard, has a very high boiling point, is insoluble in water and does not conduct electricity
- SiO2 is cheap since it is available naturally and is used to make sandpaper and to line the inside of furnaces
- Metallic Bonding
- Metal atoms are held together strongly by metallic bonding in a giant metallic lattice