Reaction Orders
How to determine reaction orders from graphs
- Reaction orders can be determined by using graphical representations of experimental data
- Two different types of graphs can be used:
- Concentration-time graphs
- Rate-concentration graphs
- Rate-concentration graphs show the distinction between zero, first and second order more clearly than concentration-time graphs, as shown below
Reaction Order Using Concentration-Time Graphs
- In a zero-order reaction, the concentration of the reactant is inversely proportional to time
- This means that the reactant concentration decreases as time increases
- The graph is a straight line going down as shown:
Concentration-time graph of a zero-order reaction
A concentration-time graph of a zero-order reaction shows that concentration is inversely proportional to time
- The gradient of the line is the rate of reaction
- Calculating the gradient at different points on the graph, will give a constant value for the rate of reaction
- When the order with respect to a reactant is 0, a change in the concentration of the reactant has no effect on the rate of the reaction
- Therefore:
Rate = k
- This equation means that the gradient of the graph is the rate of reaction as well as the rate constant, k
- In a first-order reaction, the concentration of the reactant decreases with time
- The graph is a curve going downwards and eventually plateaus:
Concentration-time graph of a first-order reaction
A concentration-time graph of a first-order reaction curves downwards
- In a second-order reaction, the concentration of the reactant decreases more steeply with time
- The concentration of reactant decreases more with increasing time compared to a first-order reaction
- The graph is a steeper curve going downwards:
Concentration-time graph of a second-order reaction
A concentration-time graph of a second-order reaction shows a downward curve with a steeper gradient than the curve for a first-order reaction
Exam Tip
- Make sure that you know the correct shapes for the concentration-time graphs
- It can be easy to confuse some concentration-time graphs with the following rate-concentration graphs, particularly:
- The straight line of a zero-order concentration-time graph with the straight line of a first-order rate-concentration graph.
- The curve of a first-order concentration-time graph with the curve of a second-order rate-concentration graph.
Reaction order using rate-concentration graphs
- In a zero-order reaction, the rate does not depend on the concentration of the reactant
- The rate of the reaction, therefore, remains constant throughout the reaction
- The graph is a horizontal line
- The rate equation is rate = k
Rate-concentration graph of a zero-order reaction
A rate-concentration graph of a zero-order reaction shows a horizontal line
- In a first-order reaction, the rate is directly proportional to the concentration of a reactant
- The rate of the reaction increases as the concentration of the reactant increases
- This means that the rate of the reaction decreases as the concentration of the reactant decreases when it gets used up during the reaction
- The graph is a straight line
- The rate equation is rate = k[A]
Rate-concentration graph of a first-order reaction
A rate-concentration graph of a first-order reaction shows a directly proportional relationship
- In a second-order reaction, the rate is directly proportional to the square of concentration of a reactant
- The rate of the reaction increases more as the concentration of the reactant increases
- This means that the rate of the reaction decreases more as the concentration of the reactant decreases when it gets used up during the reaction
- The graph is a curved line
- The rate equation is rate = k[A]2
Rate-concentration graph of a second-order reaction
A rate-concentration graph of a second-order reaction shows an upward curve
Exam Tip
- Careful: Sometimes when asked to complete calculations for the rate constant, k, the exam question will give you a graph as well as tabulated data
- Do not ignore the graph as this demonstrates the order of one of the reactants, while the tabulated data allows you to determine the order for the other reactants.