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Allotropes of Carbon Topic 4.2. Covalent Crystalline Solids There are substances which have a crystalline structure in which all the atoms are linked.

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Presentation on theme: "Allotropes of Carbon Topic 4.2. Covalent Crystalline Solids There are substances which have a crystalline structure in which all the atoms are linked."— Presentation transcript:

1 Allotropes of Carbon Topic 4.2

2 Covalent Crystalline Solids There are substances which have a crystalline structure in which all the atoms are linked together by covalent bonds. Effectively, the crystal is a single molecule with a regular repeating pattern of covalent bonds, so is often referred to as a giant molecular structure or a macromolecule.

3 Allotropes of Carbon Allotropes are different forms of an element in the same physical state. Carbon has three allotropes: graphite, diamond, and fullerene. Different bonding within these structures give rise to distinct forms with different properties

4 Graphite In graphite, each carbon atom is covalently bonded to 3 others, forming hexagons in parallel layers with bond angles of 120 o. The layers are held only by weak van der Waals’ forces, so they can slide over each other.

5 Graphite

6 Density: 2.26 g cm -3 Contains one non-bonded, delocalized electron per atom, so it conducts electricity Non-lustrous, grey solid Used as a lubricant and in pencils

7 Diamond Each carbon atom is covalently bonded to 4 others, tetrahedrally arranged in a regular repeating pattern with bond angles of 109.5 o. It is the hardest known natural substance

8 Diamond

9 Density: 3.51 g cm -3 All electrons are bonded; non conductor of electricity Lustrous crystal Polished for jewellery and ornamentation; used in tools and machinery for grinding and cutting glass.

10 Fullerene (C 60 ) Each carbon atom is bonded in a sphere of 60 carbon atoms, consisting of 12 pentagons and 20 hexagons. The structure is a closed spherical cage in which each carbon is bonded to 3 others

11 Fullerene

12 Density: 1.72 g cm -3 Easily accepts electrons to form ions Yellow crystalline solid Reacts with K to make superconducting crystalline material; related forms are used to make nanotubes for the electronics industry, catalysts and lubricants.

13 Silicon and Silicon Dioxide Like carbon, silicon is a Group 4 element and so its atoms have four valence shell electrons. In the elemental state, each silicon atom is covalently bonded to four others ina tetrahedral arrangement. This results in a giant lattice structure much like a diamond

14 Silicon Dioxide SiO 2, commonly known as silica or quartz, also forms a giant covalent structure. This is structure is also a tetrahedrally bonded structure with bonds between Si and O atoms. Each Si atom is covalently bonded to four oxygen atoms and each O to two Si Atoms

15 Silicon Dioxide Note the formula is SiO 2 and refers to the ratio of atoms within the giant molecule – the actual number of atoms present will be a very large multiple of this. The structure is strong, insoluble in water, has a high melting point, and does not conduct electricity or heat. These are all properties associated with glass and sand – different forms of silica.

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