Interpretation:
Rate law and the rate constant for the gas-phase reaction of nitrogen dioxide with ozone has to be given.
Answer to Problem 13.41QE
Rate law for the given reaction is
Explanation of Solution
The reaction between nitrogen dioxide and ozone to produce nitrogen trioxide and oxygen is given be the equation shown below;
Relative concentration of the reactant is determined by dividing the concentration of each reactant by the smallest concentration of the reactant. Relative rate of the reaction is determined by dividing the rate of the reaction by the smallest rate that is obtained from the experimental data.
The relative concentration of
Expt | Initial | Initial | Initial rate of the reaction | Relative | Relative | Relative rates of the reaction |
From the above table, it is found that in experiments 1, and 2, the concentration of ozone remains constant while the relative rate of the reaction increases in relative manner as the concentration of
From the above table, it is found that in experiments 3, and 4, the concentration of nitrogen dioxide remains constant while the relative rate of the reaction doubles as the concentration of
Rate law:
Rate law is the relationship between the concentration of the reactants and the rate of the reaction. The rate law equation is given as the rate of the reaction that is directly proportional to the product of the reactant concentration that is raised to the power of the respective reactant coefficient. Therefore, the rate law for the given reaction is as follows;
Where,
Rate constant:
The rate constant for the reaction can be calculated from the rate law using the initial concentration of the reactants as shown below;
Rearranging the above equation in order to calculate the rate constant;
Substituting the values for rate and the concentration of the reactants in the above equation, the rate constant of the reaction is calculated as shown below;
Therefore, the rate constant for the reaction is
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Chapter 13 Solutions
Chemistry: Principles and Practice
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