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Ionic Compounds Simplified Revision Notes for GCSE Edexcel Chemistry Combined Science
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2.1.3 Ionic Compounds
Formation of Ionic Compounds:
- When a chemical reaction occurs, new bonds are formed.
- Ionic compounds form by the transfer of electrons from a metal to a non-metal atom. This process creates charged particles called ions.
Example:
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In sodium chloride (NaCl), one electron is transferred from the outer shell of a sodium atom to the outer shell of a chlorine atom.
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This creates a full stable outer orbit (shell) for the two particles.
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The sodium atom becomes a positive sodium ion (Na⁺).
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The chlorine atom becomes a negative chloride ion (Cl⁻).
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Strong electrostatic attraction between the opposite charges (positive and negative) holds the ionic compound together.
Overall charge: There is no charge because the positive and negative charges cancel each other out.
The Ionic Lattice
An ionic compound is a giant structure of ions arranged in a regular, repeating pattern known as an ionic lattice. The lattice is formed because the ions attract each other, arranging themselves so that oppositely charged ions are next to each other, creating a stable structure.
The diagrams provided show different models of the ionic lattice:
Two-Dimensional Space-Filling Model: This model illustrates how ions are arranged in a regular pattern in one layer of the lattice.
- Advantage: Clearly shows how ions are arranged in a single layer, making it easy to understand the alternating pattern of positive and negative ions.
- Limitation: Does not show how ions are arranged in the next layer or in three dimensions.
Three-Dimensional Space-Filling Model: This model shows how ions are arranged in multiple layers within the lattice.
- Advantage: Provides a more accurate representation of how closely packed the ions are within the lattice.
- Limitation: May still be misleading if it suggests there is more space between ions than there actually is.
Ball and Stick Model: This model shows the spatial arrangement of ions in three dimensions.
- Advantage: Shows the arrangement of ions in a larger section of the crystal.
- Limitation: The use of sticks for bonds can be misleading because the forces of attraction act in all directions, not just along the sticks. Additionally, it shows empty spaces between ions, which don't exist in reality.
Scale of the Lattice: The ionic lattice is enormous; for example, a single grain of salt (sodium chloride) may contain around 1.2 × 10¹⁸ ions (1,200,000,000,000,000,000). The lattice extends in all directions, which is why solid ionic compounds form crystals with regular shapes.
Ionic Bonding
The ionic lattice is held together by strong electrostatic forces of attraction between oppositely charged ions. These forces act in all directions within the lattice, ensuring the structure is stable and giving ionic compounds their characteristic properties. This type of bonding is called ionic bonding.
Properties of Ionic Compounds
Ionic compounds have regular structures known as giant ionic lattices. Within these lattices, strong electrostatic forces of attraction act in all directions between the oppositely charged ions. The structure and bonding of ionic compounds directly explain their properties.
Compounds have completely different properties from the elements that form them.
Example:
- Fe (Iron): A lustrous, magnetic metal.
- S (Sulfur): A bright yellow non-metal powder.
- When combined, they form FeS (Iron sulfide): A dull grey, non-magnetic solid lump.
1. High Melting Points and Boiling Points
Ionic compounds have high melting and boiling points, which means they are typically in the solid state at room temperature.
Energy and Phase Changes:
- Melting: To melt an ionic compound, energy must be transferred to overcome some of the strong electrostatic forces of attraction between the ions.
- Boiling: To boil an ionic compound, even more energy is needed to overcome all remaining electrostatic forces.
- The More Energy Required: The higher the melting or boiling point, the more energy is required to overcome the ionic bonds. This is why ionic compounds, with their strong electrostatic attractions, have high melting and boiling points.
Explanation
- Ionic Bonding: Ionic compounds are held together by electrostatic forces between oppositely charged ions. These forces, referred to as ionic bonding, are very strong. Because a giant ionic lattice contains a large number of ions, a significant amount of energy is needed to break these bonds, resulting in high melting and boiling points.
- Strength of Ionic Bonds: The strength of the ionic bonds depends on the charge of the ions:
- Ions with higher charges create stronger forces of attraction, requiring even more energy to overcome these forces.
Example:
- Sodium chloride (NaCl): Melting point = 801°C, Boiling point = 1,413°C.
- Magnesium oxide (MgO): Melting point = 2,852°C, Boiling point = 3,600°C.
- Explanation: The ionic bonds between Mg²⁺ and O²⁻ ions are stronger than those between Na⁺ and Cl⁻ ions, resulting in higher melting and boiling points for MgO.
2. Conducting Electricity
- Requirements for Conductivity:
- A substance can conduct electricity if it contains charged particles, such as ions, and these particles are free to move from place to place.
- Ionic Compounds and Conductivity:
- In the Solid State: Ionic compounds cannot conduct electricity because the ions are held in fixed positions and cannot move.
- When Melted or Dissolved: Ionic compounds can conduct electricity when they have melted to form a liquid or when they have dissolved in water to form an aqueous solution. Both processes free the ions, allowing them to move and carry an electric current.
Key Fact: Ionic compounds conduct electricity when melted or in solution, but they act as insulators when in the solid state.
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