C2.3.3 Properties of Giant Covalent Structures

Cards (42)

  • Giant covalent structures form a continuous lattice where each atom is bonded to multiple neighbors
    True
  • Giant covalent structures have high melting and boiling points due to the strong covalent bonds
  • Match the giant covalent structure with its properties:
    Diamond ↔️ Extremely hard, thermal conductor, electrically insulating
    Graphite ↔️ Soft, good electrical conductor, lubricates surfaces
    Silicon Dioxide ↔️ Hard, chemically inert, high melting point
  • The absence of free electrons in most giant covalent structures leads to electrical insulation
  • All giant covalent structures are electrical insulators.
    False
  • Giant covalent structures have a vast network of atoms held together by strong covalent bonds
  • Giant covalent structures are hard because their strong covalent bonds require significant energy to break.

    True
  • Diamond has a melting point above 3550
  • Graphite is a good electrical conductor because it has mobile electrons between layers.

    True
  • Common examples of giant covalent structures include diamond, graphite, and silicon dioxide
  • What are the properties of diamond?
    Extremely hard, excellent thermal conductor, electrically insulating
  • Why is graphite a good electrical conductor?
    Delocalized electrons
  • Steps involved in explaining the high melting and boiling points of giant covalent structures:
    1️⃣ Strong covalent bonds form a continuous lattice
    2️⃣ Significant energy is required to break these bonds
    3️⃣ High temperatures are needed to melt or boil the substance
  • Giant covalent structures have low melting and boiling points.
    False
  • Why do giant covalent structures have high melting and boiling points?
    Strong covalent bonds
  • Graphite conducts electricity due to delocalized electrons.

    True
  • What type of bonds must be broken to melt or boil a giant covalent structure?
    Strong covalent bonds
  • Silicon dioxide has a melting point of 1713°C.
  • Why is graphite an exception to the electrical insulation rule in giant covalent structures?
    Delocalized electrons
  • Match the giant covalent structure with its electrical conductivity:
    Diamond ↔️ Insulator
    Graphite ↔️ Conductor
  • What are the uses of graphite?
    Pencils, lubricants, electrodes
  • Giant covalent structures are substances with a large lattice composed of strong covalent bonds
  • What is a key property of giant covalent structures regarding electrical conductivity?
    Most are insulators
  • Name two real-life examples of giant covalent structures.
    Diamond and graphite
  • Giant covalent structures have high melting and boiling points because strong covalent bonds require significant energy to break.

    True
  • Why are the melting and boiling points of giant covalent structures high?
    Strong covalent bonds
  • Arrange the following giant covalent structures in order of increasing electrical conductivity:
    1️⃣ Diamond
    2️⃣ Silicon Dioxide
    3️⃣ Graphite
  • What is the primary reason for the hardness of giant covalent structures?
    Robust covalent networks
  • What type of bonding is present in giant covalent structures that contributes to their high melting and boiling points?
    Strong covalent bonds
  • Match the giant covalent structure with its structure:
    Diamond ↔️ Tetrahedral lattice
    Graphite ↔️ Layers of hexagonal rings
    Silicon Dioxide ↔️ Three-dimensional network
  • What defines a giant covalent structure?
    Large lattice of strong bonds
  • Diamond has a tetrahedral lattice structure.

    True
  • Match the substance with its structure:
    Diamond ↔️ Tetrahedral lattice
    Graphite ↔️ Layers of hexagonal rings
    Silicon Dioxide ↔️ Three-dimensional network
  • Silicon dioxide is used in the production of glass, ceramics, and electronic components
  • What characteristic of giant covalent structures contributes to their thermal stability?
    High bond strength
  • Giant covalent structures are generally electrical insulators, except for graphite
  • What property of giant covalent structures requires significant energy to break bonds?
    High melting/boiling points
  • Match the property of giant covalent structures with its description:
    Melting and Boiling Points ↔️ High due to strong covalent bonds
    Electrical Conductivity ↔️ Mostly insulating, except graphite
    Hardness ↔️ Very hard due to robust bonding
  • Giant covalent structures are suitable for high-temperature applications due to their thermal stability.

    True
  • Diamond is an electrical insulator, while graphite is a conductor.