Metals Flashcards
Structure and bonding of metals
Metals have a giant metallic lattice structure, they contain strong electrostatic forces of attraction between cations and the sea of delocalised electrons.
Physical properties of metals
- High melting/boiling point (except Group 1 and Mercury)
- metals have giant metallic lattice structures, a high amount of energy is required to overcome the strong electrostatic forces of attraction between the cations and the sea of delocalised electrons. - Good conductor of heat and electricity
- The mobile delocalised electrons can act as mobile charge carriers and conduct heat. - Malleable
Pure metals contain atoms of the same size and are arranged in a regular, orderly manner allowing the layers of atoms to slide over one another easily when a force is applied. - High density
Metals contain giant metallic lattice of closely packed cations. Hence, they have high density as they have a high mass in a given unit volume
Alloys
A mixture of a metal with one or more elements
Alloys are stronger and harder than pure metal
Size of the atoms of the added element is different in size from the atoms of the parent metals. This disrupt the regular, orderly arrangement of the parent metal atoms, making it more difficult for the layers of atoms to slide over each other.
Decomposition of metal carbonates
K,Na: do not decompose (very reactive metals, carbonates are very thermally stable)
Ca-Cu: decompose into metal oxide + CO2
Ag: decompose into silver and CO2
Reduction of Metal Oxide with Carbon
K-Al: cannot be reduced by carbon
Zn-Cu: reduced by carbon to form metal + CO2
Reduction of metal oxide with hydrogen
K-Zn: cannot be reduced by hydrogen
Fe-Cu: reduced by hydrogen to form metal + steam
Why does K-Al use electrolysis in their extraction?
They are highly reactive metals, their compounds are very stable and requires a lot if energy to extract them.
Main composition of haematite
Iron (II) oxide and silicon dioxide
Blast furnace is lined with refractory materials.
Al2O3 and MGO has high melting points, they can trap heat.
Raw materials for extraction of iron
Haematite
Coke
Limestone
Key reaction in extraction of iron
Production of carbon dioxide:
C + O2 (from air) -> CO2
Production of carbon monoxide (RA):
CO2 + C -> 2CO
Reduction of haematite by CO:
Fe2O3 + 3 CO -> 2 Fe + 3 CO2
Removal of acidic impurities:
CaCO3-> CaO (base) + CO2
CaO + SiO2 -> CaSiO3(slag, float on top of the molten iron as it is less dense. Used to make roads.)
Why are raw iron extracted from the blast furnace not suitable for use?
They are too brittle to be useful as it contain a high percentage of carbon, this iron is converted to mild steel by blowing oxygen through the molten iron to oxidise som of the carbon into carbon dioixde
