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Chapter 7: Allotropes of Carbon and Metallic Bonding

7.1-Allotropes of Carbon

Diamond is very hard

  • Diamond has a giant covalent structure, made up of carbon atoms that each form four covalent bonds.

    • This makes diamond really hard

  • Those strong covalent bonds take a lot of energy to break and give diamonds a very high melting point

  • It doesn’t conduct electricity because it has no free electrons or ions

Graphite contains sheets of hexagons

  • In graphite, each carbon atom only forms three covalent bonds creating sheets of carbon atoms arranged in hexagons

  • There aren’t any covalent bonds between the layers-they’re only held together weakly, so they’re free to move over

    • This makes graphite soft and slippery, so it’s ideal as a lubricating material

  • Graphite’s got a high melting point-the covalent bonds in the layers need loads of energy to break

  • Only three out of each carbon’s four covalent electrons are used in bonds, so each carbon atom has one electron that’s delocalised(free) and can move

  • So graphite conducts electricity and thermal energy

Graphene is one layer of graphite

  • Graphene is a sheet of carbon atoms joined together in hexagons

  • The sheet is just one atom thick, making it two-dimensional compound

  • The network of covalent bonds makes it very strong

    • It’s also incredibly light, so can be added to composite materials to improve their strength without adding much weight

  • Like graphite, it contains delocalised electrons so can conduct electricity through the whole structure

    • This means it has the potential to be used in electrons

Fullerenes form sphere and tubes

  • Fullerenes are molecules of carbon, shaped like closed tubes or hollow balls

  • They’re mainly made up of carbon atoms arranged in hexagons, but can also contain pentagons(rings of five carbon atoms) or heptagons(rings of seven carbon atoms).

  • Fullerenes can be used to ‘cage’ other molecules

    • The fullerenes structure forms around another atom or molecule, which is then trapped inside

    • This could be used to deliver a drug into the body

  • Fullerenes have a surface area, so they could make great industrial catalysts, individual catalyst molecules could be attached to the fullerenes

7.2-Metallic Bonding

Metallic bonding involves delocalised electrons

  • Metals also consist of a giant structure

  • The electrons in the outer shell of the metal atoms are delocalised

    • There are strong forces of electrostatic attraction between the positive metal ions and the shared negative electrons

  • These forces of attraction hold the atoms together in a regular structure and are known as metallic bonding

    • Metallic bonding is very strong

  • Substances that are held together by metallic bonding include metallic elements and alloys

  • It’s the delocalised electrons in the metallic bonds which produce all the properties of metals

Most metals are solid at room temperature

  • The electrostatic forces between the metal atoms and the delocalised sea of electrons are very strong, so need lots of energy to be broken

  • This means that most compounds with metallic bonds have very high melting and boiling points, so they’re generally solid at room temperature

Metals are good conductors of electricity and heat

  • The delocalised electrons carry electrical current and thermal energy through the whole structure, so metals are good conductors of electricity and heat

Most metals are malleable

  • The layers of atoms in a metal can slide over each other, making metals malleable, this means that they can be bent or hammered or rolled into flat sheets

Alloys are harder than pure metals

  • Pure metals often aren’t quite right for certain jobs, they’re often too soft when they’re pure so are mixed with other metals to make them harder

  • Most of the metals we use everyday are alloys, a mixture of two or more metals or a metal and another element

    • Alloys are harder and so more useful than pure metals

    • Different elements have different sized atoms, so when another elements is mixed with a pure metal, the new metal will distort the layers of metal atoms, making it more difficult for them to slide over each other

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Chapter 7: Allotropes of Carbon and Metallic Bonding

7.1-Allotropes of Carbon

Diamond is very hard

  • Diamond has a giant covalent structure, made up of carbon atoms that each form four covalent bonds.

    • This makes diamond really hard

  • Those strong covalent bonds take a lot of energy to break and give diamonds a very high melting point

  • It doesn’t conduct electricity because it has no free electrons or ions

Graphite contains sheets of hexagons

  • In graphite, each carbon atom only forms three covalent bonds creating sheets of carbon atoms arranged in hexagons

  • There aren’t any covalent bonds between the layers-they’re only held together weakly, so they’re free to move over

    • This makes graphite soft and slippery, so it’s ideal as a lubricating material

  • Graphite’s got a high melting point-the covalent bonds in the layers need loads of energy to break

  • Only three out of each carbon’s four covalent electrons are used in bonds, so each carbon atom has one electron that’s delocalised(free) and can move

  • So graphite conducts electricity and thermal energy

Graphene is one layer of graphite

  • Graphene is a sheet of carbon atoms joined together in hexagons

  • The sheet is just one atom thick, making it two-dimensional compound

  • The network of covalent bonds makes it very strong

    • It’s also incredibly light, so can be added to composite materials to improve their strength without adding much weight

  • Like graphite, it contains delocalised electrons so can conduct electricity through the whole structure

    • This means it has the potential to be used in electrons

Fullerenes form sphere and tubes

  • Fullerenes are molecules of carbon, shaped like closed tubes or hollow balls

  • They’re mainly made up of carbon atoms arranged in hexagons, but can also contain pentagons(rings of five carbon atoms) or heptagons(rings of seven carbon atoms).

  • Fullerenes can be used to ‘cage’ other molecules

    • The fullerenes structure forms around another atom or molecule, which is then trapped inside

    • This could be used to deliver a drug into the body

  • Fullerenes have a surface area, so they could make great industrial catalysts, individual catalyst molecules could be attached to the fullerenes

7.2-Metallic Bonding

Metallic bonding involves delocalised electrons

  • Metals also consist of a giant structure

  • The electrons in the outer shell of the metal atoms are delocalised

    • There are strong forces of electrostatic attraction between the positive metal ions and the shared negative electrons

  • These forces of attraction hold the atoms together in a regular structure and are known as metallic bonding

    • Metallic bonding is very strong

  • Substances that are held together by metallic bonding include metallic elements and alloys

  • It’s the delocalised electrons in the metallic bonds which produce all the properties of metals

Most metals are solid at room temperature

  • The electrostatic forces between the metal atoms and the delocalised sea of electrons are very strong, so need lots of energy to be broken

  • This means that most compounds with metallic bonds have very high melting and boiling points, so they’re generally solid at room temperature

Metals are good conductors of electricity and heat

  • The delocalised electrons carry electrical current and thermal energy through the whole structure, so metals are good conductors of electricity and heat

Most metals are malleable

  • The layers of atoms in a metal can slide over each other, making metals malleable, this means that they can be bent or hammered or rolled into flat sheets

Alloys are harder than pure metals

  • Pure metals often aren’t quite right for certain jobs, they’re often too soft when they’re pure so are mixed with other metals to make them harder

  • Most of the metals we use everyday are alloys, a mixture of two or more metals or a metal and another element

    • Alloys are harder and so more useful than pure metals

    • Different elements have different sized atoms, so when another elements is mixed with a pure metal, the new metal will distort the layers of metal atoms, making it more difficult for them to slide over each other