Reversible Reactions PDF
Reversible Reactions PDF
Reversible Reactions PDF
1. Reversible Reactions
A reversible reaction is a chemical in which the products can
be converted back to reactants under suitable conditions.
A reversible reaction is shown by the sign a half-arrow to the right (forward reaction) and a
half-arrow to the left (backward reaction).
Most reactions are not reversible and have the usual complete arrow only pointing to the
right.
On heating strongly, the white solid ammonium chloride, decomposes into a mixture of two
colourless gases ammonia and hydrogen chloride.
On cooling the reaction is reversed and solid ammonium chloride reforms.
o This is an example of sublimation but involving both physical and chemical changes.
o Ammonium chloride + heat ammonia + hydrogen chloride
On heating the blue solid, hydrated copper(II) sulphate, steam is given off and the white solid of
anhydrous copper(II) sulphate is formed.
When the white solid is cooled and water added, blue hydrated copper(II) sulphate is reformed.
blue hydrated copper(II) sulphate + heat white anhydrous copper(II) sulphate + water
Note:
The 5H2O in the formula of hydrated copper(II) sulphate is called the water of crystallisation
and forms part of the crystal structure when copper(II) sulphate solution is evaporated and crystals
form.
This crystal structure is broken down on heating and the water is given off.
The thermal decomposition is endothermic as heat is absorbed to drive off the water.
The reverse reaction is exothermic ie on adding water to white anhydrous copper(II) sulphate the
mixture heats up as the blue crystals reform.
The reverse reaction is used as a simple chemical test for water ie white anhydrous copper(II)
sulphate turns blue.
A reversible reaction is one in which the products of a reaction can react back to produce
the original reactants. The reaction can go both ways:
If the reaction is carried out in a closed container, a point is reached where the
concentration of products and reactants does not change. We say that an equilibrium
(balance) has been reached.
The amounts of reactants and products present at equilibrium depend on the temperature,
pressure and concentration of reactants at the start.
If we remove the products from an equilibrium reaction more reactants are converted to
products.
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Equation Effect of increasing pressure
N2(g) +
2NH3(g) 2 More ammonia is formed. Increasing the pressure
3H2(g) 4 <=>
molecules pushes the reaction in the direction of fewer molecules.
molecules
N2O4(g) 1 2NO2(g) 2 More N2O4(g) is formed. Increasing the pressure
<=>
molecule molecules pushes the reaction in the direction of fewer molecules.
H2(g) + I2(g) 2 2HI(g) 2 No effect, because there are the same number of
<=>
molecules molecules molecules on each side of the equation.
When a reversible reaction occurs in a closed system an equilibrium is formed, in which the
original reactants and products formed coexist.
In an equilibrium there is a state of balance between the concentrations of the reactants and
products.
At equilibrium the rate at which the reactants change into products is exactly equal to the rate at
which the products change back to the original reactants.
The result is that that the concentrations of the reactants and products remain the same BUT the
reactions don't stop!
However the relative amounts of the reactants and products depend on the reaction conditions eg
the temperature and pressure.
For industrial processes, it is important to maximise the concentration of the desired products and
minimise the 'leftover' reactants. A set of rules can be used to predict the best reaction conditions to
give the highest possible yield of product.
Rule 1a: If the forward reaction forming the product is endothermic, raising the temperature favours
its formation increasing the yield of product (lowering the temperature decreases the yield).
Rule 1b: If the forward reaction forming the product is exothermic, decreasing the temperature favours its
formation (increasing temperature decreases the yield).
Rule 1 applies to any reaction BUT rule 2 applies to a reaction with one or gaseous reactants or products.
Rule 2a: Increasing the pressure favours the side of the equilibrium with the least number of
gaseous molecules as shown by the balanced symbol equation.
Rule 2b: Decreasing the pressure favours the side of the equilibrium with the most number of gaseous
molecules as shown by the balanced symbol equation
Rule 3a: If the concentration of a reactant (on the left) is increased, then some of it must change to the
products (on the right) to maintain a balanced equilibrium position.
Rule 3b: If the concentration of a reactant (on the left) is decreased, then some of the products (on the
right) must change back to reactants to maintain a balanced equilibrium position.
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decreasing ammonia => decreases nitrogen and hydrogen
decreasing nitrogen ==> increases hydrogen and decreases ammonia
decreasing hydrogen ==> increases nitrogen and decreases ammonia
Rule 4: A catalyst does NOT affect the position of an equilibrium, you just get there faster! A
catalyst usually speeds up both the forward and reverse reaction but there is no way it can influence the
final 'balanced' concentrations. However, the importance of a catalyst lies with economics eg (i) bringing
about reactions with high activation energies at lower temperatures and so saving energy or (ii) saving time
is saving money.
(a) The formation of calcium oxide (lime) and carbon dioxide from calcium
carbonate (limestone)
The forward reaction is endothermic, 178kJ of heat energy is absorbed (taken in) for every mole of calcium
oxide formed.
One mole of gas is formed in the process, so there is a net increase in the moles of gas in lime formation,
since there are no gaseous reactants.
From rule 1: increasing the temperature will increase the yield of lime CaO (endothermic).
From rule 2: decreasing the pressure will favour the formation of more carbon dioxide, hence more lime
(increase in gas molecules).
Lime is made commercially by heating limestone to a high temperature (eg 1000 oC) in a limekiln that is well
ventilated (this reduces the carbon dioxide pressure and so reduces the un-desired backward reaction).
The forward reaction is exothermic, 184kJ of heat energy is given out in forming hydrogen chloride (92 kJ
per mole of HCl formed).
There is no net change in the moles of gas (2 moles reactants 2 moles of product)
From rule 1: decreasing the temperature favours the formation of hydrogen chloride HCl
From rule 2: since there is no net change in the moles of gas, pressure has no effect on the yield of
hydrogen chloride!
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3. The Synthesis of ammonia - The Haber Process
Ammonia gas is synthesised in the chemical industry by reacting nitrogen gas with
hydrogen gas.
The nitrogen is obtained from air (80% of air is N2).
The hydrogen is made by reacting methane (natural gas) and water or from cracking
hydrocarbons (both reactions are done at high temperature with a catalyst).
o CH4 + H2O ==> 3H2 + CO
o eg C8H18 ==> C8H16 + H2
The synthesis equation for this reversible reaction is ...
DONE