bonding and structure

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Created by
zaynah riasat

Cards (30)

  • Compounds
    Substances in which 2 or more elements are chemically combined
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  • Types of strong chemical bonds
    • Ionic
    • Covalent
    • Metallic
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  • Ionic bonding
    • Particles are oppositely charged ions
    • Occurs in compounds formed from metals combined with non-metals
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  • Covalent bonding

    • Particles are atoms which share pairs of electrons
    • Occurs in most non-metallic elements and in compounds of non-metals
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  • Metallic bonding

    • Particles are atoms which share delocalised electrons
    • Occurs in metallic elements and alloys
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  • Ionic bonding formation
    1. Metal atoms lose electrons to become positively charged ions
    2. Non-metal atoms gain electrons to become negatively charged ions
    3. Ions produced by metals in Groups 1 and 2 and by non-metals in Groups 6 and 7 gain full outer shell of electrons
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  • Ionic compound example
    • Sodium chloride (salt)
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  • Ionic compounds
    Giant structure of ions held together by strong electrostatic forces of attraction between oppositely charged ions
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  • Covalent bonding

    • Atoms share one or more pairs of electrons
    • Small molecules have strong covalent bonds within their molecules
    • Polymers are large covalently bonded molecules
    • Giant covalent structures consist of many atoms covalently bonded in a lattice structure
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  • Metallic bonding
    • Positive ions (atoms that have lost electron(s)) and delocalised electrons arranged in a regular pattern
    • Delocalised electrons are free to move through the structure
    • Delocalised electrons are shared through the structure so metallic bonds are strong
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  • The three states of matter
    • Solid
    • Liquid
    • Gas
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  • Melting and freezing
    Take place at the melting point
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  • Boiling and condensing
    Take place at the boiling point
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  • Particle theory
    • The amount of energy needed to change state depends on the strength of the forces between the particles
    • The nature of the particles involved depends on the type of bonding and the structure of the substance
    • The stronger the forces between the particles the higher the melting point and boiling point of the substance
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  • State symbols
    Solid (s), liquid (l), gas (g), aqueous (aq)
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  • Properties of ionic compounds
    • Have regular structures (giant ionic lattices) with strong electrostatic forces of attraction in all directions
    • Have high melting and boiling points
    • Conduct electricity when melted or dissolved in water but not when solid
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  • Properties of small molecules
    • Usually gases or liquids with low boiling and melting points
    • Have weak intermolecular forces between the molecules
    • Larger molecules have higher melting and boiling points
    • Don't conduct electricity
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  • Polymers
    • Have very large molecules
    • Atoms in the polymer molecules are linked by strong covalent bonds
    • Intermolecular forces between polymer molecules are relatively strong so they are solids at room temperature
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  • Giant covalent structures
    • Substances with very high melting points where all atoms are linked by strong covalent bonds
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  • Giant covalent structures
    • Diamond, graphite, silicon dioxide
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  • Properties of metals and alloys
    • Metals have giant structures of atoms with strong metallic bonding
    • Most metals have high melting and boiling points
    • Layers of atoms can slide over each other
    • Alloys are harder than pure metals because different sized atoms distort the layers
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  • Metals as conductors
    Good conductors of electricity and thermal energy due to delocalised electrons
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  • Diamond
    • Each carbon is joined to 4 other carbons covalently
    • Very hard, high melting point, does not conduct electricity
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  • Graphite
    • Each carbon is covalently bonded to 3 other carbons, forming layers with weak intermolecular forces between them
    • Soft and slippery
    • One electron from each carbon atom is delocalised, allowing it to conduct electricity
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  • Graphene
    • Single layer of graphite
    • Very strong and elastic due to tight covalent bonding within layers
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  • Fullerenes
    • Molecules of carbon atoms with hollow shapes based on hexagonal rings, may also contain 5 or 7 membered rings
    • First discovered was Buckminsterfullerene (C60) with a spherical shape
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  • Carbon nanotubes
    • Cylindrical fullerenes with very high length to diameter ratios
    • Useful for nanotechnology, electronics and materials
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  • Nanoparticles
    • 1-100 nanometers across, containing a few hundred atoms
    • Have different properties to the 'bulk' chemical due to high surface area to volume ratio
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  • Uses of nanoparticles
    • Good catalysts
    • Highly selective sensors
    • Stronger, lighter building materials
    • New cosmetics
    • Lubricant coatings
    • Small electrical circuits
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  • Possible disadvantages of nanoparticles: there are some concerns that they may be toxic to people and able to enter the brain from the bloodstream
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