Topic 4

Created by

Naomi A

Cards (45)

Metal reacts with cold water
Metal hydroxide and hydrogen gas
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Metal reacts with steam
Metal oxide and hydrogen gas
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Reaction when calcium reacts with cold water
Ca + 2H2O → Ca(OH)2 + H2
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Reaction when zinc reacts with steam 
Zn + H2O → ZnO +H2
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Metal reacts with dilute acid
Salt and hydrogen
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Metal reacts with cold water
Suggests the metal is very reactive as only the most reactive metals can react with cold water
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Metal reacts with oxygen but not acid or cold water 
Not very reactive, most metals react with oxygen
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Metal which will not react with water, acid or oxygen
Gold
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Experiment to compare reactivity of two metals using displacement 
1. Add a solid metal to a salt solution (the salt must contain a different metal)
2. If the solid metal is more reactive, it will gradually disappear, displacing the metal that was in the salt solution
3. If nothing happens, the metal in the salt is more reactive and can't be displaced
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Magnesium is added to copper sulfate solution 
The copper sulfate solution is blue. Magnesium is more reactive than copper so when magnesium is added the blue solution decolourises and copper coats the surface of the magnesium
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Displacement reaction 
Reduction and oxidation are taking place in the same reaction. The more reactive metal atoms lose electrons to form ions (oxidation) and the less reactive metal ions gain electrons to form the element (reduction)
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Reactivity of a metal
Tendency to form cations (positive ions)
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Metals highest in the reactivity series are most easily oxidised
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Most metals are extracted from ores found in the Earth's crust
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Ore 
A rock which contains metals often chemically combined with other substances
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Unreactive metals are found in the earth's crust as uncombined elements
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Oxidation 
Gain of oxygen
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Reduction 
Loss of oxygen
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Most ores contain metals chemically combined with oxygen, so reduction must be carried out to extract the metal
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Methods to extract metals from their ores
1. Reduction with carbon: Can only be done if the metal is less reactive than carbon
2. Electrolysis: Can be done with all metals, but requires a large amount of energy (high cost)
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Extracting iron from its ore
Iron is less reactive than carbon so can be extracted by reduction with carbon. Electrolysis could also be used, but this would use a lot of unnecessary energy (high cost)
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Chemical equation for reduction of iron with carbon 
2Fe2O3 + 3C → 4Fe + 3CO2
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Extracting aluminium from its ore
Aluminium is more reactive than carbon so electrolysis must be used. When the molten ore undergoes electrolysis, the metal forms at the cathode
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Aluminium oxide has a very high melting point, so it is dissolved in molten cryolite to produce an electrolyte with a lower melting point, reducing energy usage and cost
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Phytoextraction - using plants to extract metals 
Plants are grown in areas with metals in the soil. The plants take up metals through their roots and concentrate them in their shoots and leaves. These plants are burned and the metals are removed from the ash
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Bacterial extraction - using bacteria to extract metals 
Some bacteria absorb metal compounds. These bacteria produce solutions called leachates containing the metals. Scrap iron can be used to remove the metal from the leachate
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Limitations of biological methods of extraction
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Phytoextraction 
1. Plants are grown in areas with metals in the soil
2. Plants take up metals through their roots and concentrate them in their shoots and leaves
3. Plants are burned and the metals are removed from the ash
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Bacterial extraction 
1. Some bacteria absorb metal compounds
2. Bacteria produce solutions called leachates containing the metals
3. Scrap iron can be used to remove the metal from the leachate
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Limitations of biological methods of extraction
Only suitable for low grade ores with smaller quantities of metals
Slow processes
Require displacement or electrolysis for the final step
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Oxidation 
The loss of electrons
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Metals lower in the reactivity series
Are less reactive, less likely to form their cations, more resistant to oxidation
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Advantages of recycling metals
Economically beneficial because electrolysis is expensive
Prevents the detrimental environmental impact of mining and extraction of new metals
Less waste produced so less landfill
Less energy required compared to electrolysis
More sustainable - not using up the finite resources
Recycling process provides employment
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Life cycle assessment 
Analysis of the overall environmental impact that a product may have throughout its lifetime
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Factors considered in a life cycle assessment
Extraction and processing of raw materials
Manufacturing
Packaging and transportation
Use of the product
Disposal
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Reversible reaction 
A reaction in which the products can react to form the original reactants
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Dynamic equilibrium 
When the rate of the forward reaction equals the rate of the backwards reaction, so the concentration of reactants and products are constant even though compounds are continually reacting
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Closed system 
A system where nothing is added or removed, all reactants and products remain in the reaction vessel
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Equilibrium is only reached if the reaction takes place in a closed system, as this prevents any reactants and products escaping so they can react continuously
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Haber process 
An industrial process used to produce ammonia (for making fertilisers)
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