Topic 3 - chemical reactions period 2&3 Flashcards
Reactions with Oxygen
The reactions of metals with oxygen can influence how they are used
E.g. Iron reacts with oxygen to form rust so is often painted to protect it from air
The general pattern from left to right for the oxides formed by period 2 and 3 elements is:
Ionic → giant covalent → small covalent
Solids → gases
Alkaline → amphoteric → acidic
Group 1 -Lithium
Rapid reaction, burns with a red flame
Stored in oil to prevent reaction in air
Metal oxide produced which forms an alkaline solution in water 4Li(s) + O2(g) → 2Li2O(s) Oxide contains simple O2- ion
Group 1 - Sodium
Very vigorous reaction, burns with orange flame
Stored in oil to prevent reaction in air
Metal oxide produced which forms a basic solution in water
4Na(s) + O2(g) → 2Na2O(s)
2Na(s) + O2(g) → Na2O2(s)
Oxide can contain simple O2- ion or the peroxide ion O22-
Peroxides
The complicated molecular ion (O22- ) is unstable near small positive ions
The covalent bond between the two negative oxygen ions is weak
The electrons in the ions will be attracted to a positive ion BUT the positive ion can polarise the negative ion
Lithium only has a 1+ charge but is small so has a high charge density. This causes the peroxide ion to break down to an oxide ion and an oxygen atom
Therefore Lithium does not form a peroxide
Sodium is a larger ion so the O22- ion can stay stable enough to form sodium peroxide
Other group 1 metals
Potassium can form a peroxide in a similar way to sodium
2K(s) + O2(g) → K2O2(s)
Potassium, rubidium and caesium can also ignite in air to form super-oxides, KO2, RbO2 and CsO2
These super-oxides contain the molecular ion O22-
The super-oxide ions are highly unstable and only remain stable in the presence of the larger, non-polarising ions at the bottom of group 1
Group 2 - Beryllium
Needs heat to react in similar way to group 1
Very vigorous reaction
2Be(s) + O2(g) → 2BeO(s)
Forms a coating of beryllium oxide which prevents further oxidation
Oxide is basic in nature
Group 2 - Magnesium
Needs heat to react in similar way to group 1
Very vigorous reaction 2Mg(s) + O2(g) → 2MgO(s) Oxide is a base
Other group 2 metals
Strontium and Barium will also form peroxides
The general equation is:
M + O2 → MO2
Transition metals and oxygen
When transition metals (d-block) react with oxygen, the oxides formed are often brittle
Iron oxide is rust
Some d-block metals are resistant to corrosion because they form an unreactive oxide layer which protects the metal from further reaction (e.g. Titanium)
D-block metals form a range of oxides
D-block metals are much less reactive than group 1 and 2 in general
Group 3 - Boron
Burns with a brilliant flame to produce boron trioxide
4B(s) + 3O2(g) → 2B2O3(s)
Boron trioxide forms a thin film on the surface that prevents further reaction with oxygen
Boron is the only element in group 3 which is NOT a metal
Group 3 – Aluminium
Vigorous reaction at first 4Al(s) + 3O2(g) → 2Al2O3(s) forms a water-insoluble layer on the surface that prevents further reaction with oxygen Aluminium oxide is amphoteric
Other group 3 metals
Thallium will react to produce Tl2O
Group 4 - Carbon
Needs heat to react
Forms slightly acidic oxides
C(s) + O2(g) → CO2(g) complete combustion
2C(g) + O2(g) → 2CO(g) incomplete combustion
Group 4 - Silicon
Forms a thin layer of oxide which protects the rest so very little reaction Si(s) + O2(g) → SiO2(s) Silicon dioxide is slightly acidic
Other group 4 elements
Group 4 metals Lead and Tin can produce oxides with the formulae MO and MO2
