SPM Chemistry (KSSM) Paper 1

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7.2.1 Factors Affecting the Rate of Reaction

SPM Chemistry (KSSM) Paper 1 7.2 Factors Affecting the Rate of Reaction 7.2.1 Factors Affecting the Rate of Reaction
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Factors Affecting the Rate of Reaction

There are 4 factors that can affect the rate of a reaction, namely

  1. the total surface area of the reactant (solid only)
  2. the concentration of the reactant (solution only)
  3. the temperature of the reactant
  4. presense of catalyst in the reactant
  5. the pressure of the reactant (gas only)

Total Surface Area

  1. For same amount of reactant, particles with smaller size has bigger total surface area
  2. The bigger the total surface area, the higher the rate of reaction

Concentration of Solution

The higher the concentration, the higher the rate of reaction.

Temperature

The higher the temperature, the higher the rate of reaction.

Catalyst

Positive catalyst – Increase the rate of reaction.
Negative catalyst – Reduce the rate of reaction.

Pressure

  1. Only affect the reaction involve gas as reactant.
  2. The higher the pressure, the higher the rate of reaction
 

Total Surface Area

The bigger the total surface area of the reactant, the higher the rate of reaction.

  1. For reaction involves solid reactant, when the solid reactants are broken up into smaller pieces, the total surface area of the reactant becomes bigger.
  2. The bigger the total surface area of the reactant, the higher the rate of reaction.
    • The smaller the size of the particle, the bigger the total surface area. 
    • The bigger the total surface area, the higher the rate of reaction.
 

Experiment
The reaction between Hydrochloric acid, HCl and calcium carbonate, CaCO3.
CaCO₃ +2HCl → CaCl₂ +CO₂ + H₂O

Experiment 1
25 cm3 of 0.5 mol dm–3 hydrochloric acid + calcium carbonate chips. The carbon dioxide gas released is collected in a burrete. The volume of the gas released is recorded in every 30s. The result is plotted in a graph.

Experiment 2
25 cm3 of 0.5 mol dm–3 hydrochloric acid + calcium carbonate powder. As in experiment 1, the carbon dioxide gas released is collected in a burrete and the volume of the gas released is recorded in every 30s. The result is plotted in the same graph in experiment 1.
 

Conclusion

 
 
  1. The gradient of the curve for experiment 2 is greater than the curve for experiment 1. This indicate that the rate of reaction in experiment 2 is higher than experiment 1.
  2. We can conclude that, the smaller the particle size of the reactant, the bigger the total surface area, and the bigger the total surface area, the higher the rate of the reaction will be.
 

Concentration of Reactants

The higher the concentration of the solution, the higher the rate of reaction.

Experiment

By measuring the time taken for the formation of sulphur precipitate (yellow solid) when sulphuric acid, H2SO4 reacts with sodium thiosulphate(VI), Na2S2O3 of different concentration, we can investigate the effect of concentration of the reactant on the rate of reaction.
 

Procedure:
  1. 50 cm3 of 0.2 mol dm-3 sodium thiosulphate solution + 10 cm3 of 0.5 mol dm-3 sulphuric acid.
  2. Time taken for the ̔X’ sign placed under the conical flask to disappear from view is recorded.
  3. The experiment is repeated by using sodium thiosulphate solution with concentration 0.4 mol dm-3, 0.6 mol dm-3, 0.8 mol dm-3 and 1.0 mol dm-3.
Conclusion 1:
  1. The graph for the concentration of sodium thiosulphate (VI), Na2S2O3 against the time taken for the sulphur precipitate to formed is plotted.
  2. As the concentration of sodium thiosulphate solution decreases, the longer the time is needed for the marked ̔X’ to disappear.
Conclusion 2:
  1. The graph for the concentration of sodium thiosulphate (VI), Na2S203 against 1/time taken is plotted.
  2. As the concentration of sodium thiosulphate increases, the value of 1/time increases. We should note that 1/time = rate of reaction.
  3. The higher the concentration of sodium thiosulphate solution, the higher the rate of reaction.
 
 

Temperature of the Reactant

The higher the temperature of the solution, the higher the rate of reaction.

Experiment

By measuring the time taken for the formation of sulphur precipitate (yellow solid) when sulphuric acid, H2SO4 reacts with sodium thiosulphate(VI), Na2S2O3 of different temperature, we can investigate the effect of temperature of the reactant on the rate of reaction.
 

Procedure:
 
 
  1. 50 cm3 of 0.2 mol dm-3 sodium thiosulphate solution at 30ºC + 10 cm3 of 0.5 mol dm-3 sulphuric acid.
  2. Time taken for the ̔X’ sign placed under the conical flask to disappear from view is recorded.
  3. The experiment is repeated by using sodium thiosulphate solution with temperature 35ºC, 40ºC, 45ºC and 50ºC.
Conclusion 1:
  1. The graph for the temperature of sodium thiosulphate (VI), Na2S2O3 against the time taken for the sulphur precipitate to formed is plotted.
  2. As the temperature of sodium thiosulphate solution decreases, the longer the time is needed for the marked ̔X’ to disappear.
 
Conclusion 2:
  1. The graph for the temperature of sodium thiosulphate (VI), Na2S203 against 1/time taken is plotted.
  2. As the temperature of sodium thiosulphate increases, the value of 1/time increases. We should note that 1/time = rate of reaction.
  3. The higher the temperature of sodium thiosulphate solution, the higher the rate of reaction.
 
 
 

Presence of Catalyst

  1. A catalyst is a substance which can change the rate of reaction.
  2. There are 2 types of catalyst:
    1. Positive catalyst – Increase the rate of reaction.
    2. Negative catalyst – Reduce the rate of reaction.

Experiment 1

Set 1: Zinc + Hydrochloric Acid
Set 2: Zinc + Hydrochloric Acid + Copper Sulphate (Catalyst)

Chemical Reaction:

Zn + 2HCl → ZnCl2 + H2

Result:

 
 
Copper(II) sulphate acts as a catalyst to increase the rate of reaction between zinc and hydrochloric acid
 

Conclusion
The presence of catalyst increases the rate of reaction.

Experiment 2
Set 1: Decomposition of Hydrogen Peroxide
Set 2: Decomposition of Hydrogen Peroxide + Manganese(IV) Oxide (Catalyst)

Chemical Reaction: 

2H2O2 → 2H2O + O2

Result:

 
 
Manganese(IV) oxide acts as a catalyst to increase the rate of reaction between zinc and hydrochloric acid

Conclusion:
The presence of catalyst increases the rate of reaction

Note:
In SPM, you need to remember the catalyst used in both the chemical reaction above.

Characteristic of Catalyst

  1. A catalyst is a substance which can change the rate of reaction.
  2. There are a few things you need to know about catalyst:
    1. Chemically, the catalyst remains unchanged during a reaction.
    2. Catalyst does not change the quantity of products.
    3. Catalyst is specific, which means different chemical reaction may have different catalyst.
    4. Just a small amount needed to achieve a big increase in the rate of reaction.
    5. More amount of catalyst used can further increase the rate of reaction.
    6. A catalyst in powder form can further increase the rate of reaction.
    7. A catalyst may undergo a physical change in a reaction.

List of Reactions and the Catalyst

Chemical ReactionCatalyst
Decomposition of hydrogen peroxide:
2H2O2 → 2H2O + O2		Manganese(IV) oxide, MnO2
Lead(II) oxide, PbO
Lead(IV) oxide, PbO2
The reaction between Zinc and Hydrochloric Acid:
Zn + 2HCl → ZnCl2 + H2		Manganese (IV) oxide, MnO2
Copper (II) oxide, CuO
Zinc Oxide, ZnO
Silicon (IV) oxide, SiO2
Decomposition of Potassium Chlorate (V):
2KClO3 + 2KCl  3O2		 Copper (II) sulphate, CuSO4
Copper (II) chloride, CuCl2
Copper (II) nitrate, Cu(NO3)2
Haber Process
N2 + 3H2  2NH3		 Iron
Contact Process
2SO2 + O2  2SO3		 Vanadium(V) oxide, V2O5
Ostwald Process
4NH3(g) + 5O2(g)  4NO(g) + 6H2O(1)		Platinum

Pressure of Gas​

  1. For reactions involve gas, the rate of reaction is affected by the pressure of the gas.
  2. Pressure DOES NOT affect the rate of reaction where the reactants are in the form of solids or liquids.
  3. The higher the pressure of the gas, the higher the rate of reaction
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