A-Level Chemistry AQA Notes
3.1.3 Bonding
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Ions
- An ion is an atom or molecule with a net charge formed through the gain or loss of electrons
- A cation is formed from the loss of electrons
- An anion is formed from the gain of electrons
- The noble gases do not form ions, as they already have a stable full outer shell of electrons, making them unreactive.
- Molecular ions are formed when groups of two or more atoms that are covalently bonded gain or lose electrons
Charge | Molecular ion |
+1 | Ammonium: NH4+ |
-1 | Hydroxide: OH^- Nitrate: NO3- Hydrogencarbonate: HCO3- |
-2 | Carbonate: CO3^2- Sulphate: SO4^2- Sulphite: SO3^2- |
- Ionic compounds are composed of oppositely charged ions. The overall charge is zero as the ionic charges balance.
- e.g. write the formula of sodium carbonate
We need 2 x Na+ to balance the -2 charge of CO3^2-
The formula is Na2CO3
The formula is Na2CO3
Covalent Bonds
- Covalent bonding usually occurs between two atoms of non-metals, so that the atoms each gain a stable full outer shell
- A covalent bond is a strong electrostatic attraction between a shared pair of outer electrons and the nuclei of the bonded atoms
- A single covalent bond involves one shared pair of outer electrons, while a multiple covalent bond involves more than one shared pair of outer electrons
- A co-ordinate (dative covalent) bond involves one atom donating both electrons in a covalent bond.
- A dative covalent bond is represented by an arrow from the atom that is donating both electrons to the atom that is accepting both electrons
Ionic Bonding
- An ionic bond is an electrostatic attraction between positive and negative ions, resulting in a lattice
- A lattice is a giant three-dimensional structure, where each ion is surrounded by oppositely charged ions
- They are often formed between ions of metals and non-metals, where each atom aims to gain a stable full outer shell.
- Electrons are represented by dots and crosses, which helps visualise the origin of the electrons clearly
- The strength of an ionic bond depends on
- The charge on the ions- Ions with higher charges will have a greater electrostatic attraction between them
- The distance between the ions- Smaller ions have a smaller internuclear distance so the electrostatic forces of attraction will be greater, and they can pack more closely
- Properties of ionic structures
- High melting and boiling points
- Soluble in polar solvents
- Electrical conductivity when molten or dissolved in water
Metallic Bonding
- Metallic bonding is the strong electrostatic attraction between positive metal ions and negative delocalised electrons in a metal lattice
- Metals have a fixed lattice structure of positive ions. The outer shell of electrons is delocalised, which can carry current.
- Metals have high melting and boiling points due to the large amounts of energy needed to overcome the metallic bonds.
- The greater the charge of a metal ion, the more electrons are delocalised. The smaller the size of the metal ions, the closer they are to the delocalised electrons. This results in stronger bonds and a higher melting point
- Metals are malleable and ductile. The ions can slide and move past each other as there are no bonds holding specific ions together
Crystalline Structure
Simple Molecules
- Bonding pairs and lone pairs of electrons are charge clouds that repel each other
- Electron pairs in the outer shell arrange themselves as far apart as possible to minimise repulsion
- Bonding pairs repel each other equally. While lone pairs repel other pairs more because they are more electron dense.
- Each lone pair reduces the bond angle by about 2.5 degrees.
- A normal line represents the bond is in plane of the paper. A dotted wedge is a bond going into the paper and a bold wedge is a bond coming out of the paper.
Electron Pairs | Bonding Pairs | Lone Pairs | Bond Angles | Example | |
Linear | 2 | 2 | 180⁰ | CO2 | |
Trigonal Planar | 3 | 3 | 120⁰ | BF3 | |
Bent | 3 | 2 | 1 | <120⁰ | SO2 |
Tetrahedral | 4 | 4 | 109.5⁰ | CH4 | |
Trigonal Pyramidal | 4 | 3 | 1 | 107⁰ | NH3 |
V-Shaped | 4 | 2 | 2 | 104.5⁰ | H2O |
Trigonal Bipyramidal | 5 | 5 | 90⁰, 120⁰ | PCl5 | |
Seesaw | 5 | 4 | 1 | 87⁰, 102⁰ | SF4 |
T-Shaped | 5 | 3 | 2 | 88⁰ | ClF3 |
Linear | 5 | 2 | 3 | 180⁰ | XeF2 |
Octahedral | 6 | 6 | 90⁰ | SF6 | |
Square Pyramidal | 6 | 5 | 1 | <90⁰ | BrF5 |
Square Planar | 6 | 4 | 2 | 90⁰ | XeF4 |
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