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Time (minutes) | C 60 O 3 absorbance |
---|---|
3 | 0.04241 |
9 | 0.03634 |
15 | 0.03121 |
21 | 0.02680 |
27 | 0.02311 |
33 | 0.01992 |
39 | 0.01721 |
45 | 0.01484 |
51 | 0.01286 |
57 | 0.01106 |
63 | 0.00955 |
69 | 0.00827 |
75 | 0.00710 |
81 | 0.00616 |
87 | 0.00534 |
93 | 0.00461 |
99 | 0.00395 |
The rate at which the decomposition reaction is occurring is clearly related to the rate of change of theconcentration [C 60 O 3 ],which is proportional to the slope of the graph in [link] . Therefore, we define the rate of this reaction as
It is clear that the slope of the graph in [link] changes over the course of time. Correspondingly, [link] shows that the rate of the reaction decreases as the reaction proceeds. The reaction is at first very fast but then slowsconsiderably as the reactant C 60 O 3 is depleted.
The shape of the graph for rate versus time ( [link] ) is very similar to the shape of the graph for concentration versus time ( [link] ). This suggests that the rate of the reaction is related to the concentration ofC 60 O 3 at each time. Therefore, in [link] , we plot the rate of the reaction, defined in [link] and shown in [link] , versus the absorbance of theC 60 O 3 .
We find that there is a very simple proportional relationship between the rate of the reaction and theconcentration of the reactant. Therefore, we can write
As a second example of a reaction rate, we consider the dimerization reaction of butadiene gas,CH 2 =CH-CH=CH 2 . Two butadiene molecules can combine to form vinylcyclohexene, shownin [link] .
[link] provides experimental data on the gas phase concentration of butadiene[C 4 H 6 ] as a function of time at .
Time (s) | [C 4 H 6 ] (M) | Rate (M/s) | ||
---|---|---|---|---|
0 | 0.0917 | |||
500 | 0.0870 | |||
1000 | 0.0827 | |||
1500 | 0.0788 | |||
2000 | 0.0753 | |||
2500 | 0.0720 | |||
3000 | 0.0691 | |||
3500 | 0.0664 | |||
4000 | 0.0638 |
We can estimate the rate of reaction at each time step as in [link] , and these data are presented in [link] as well. Again we see that the rate of reaction decreases as theconcentration of butadiene decreases. This suggests that the rate is given by an expression like [link] . To test this, we calculate in [link] for each time step. We note that this is not a constant, so [link] does not describe the relationship between the rate of reaction and the concentration of butadiene.Instead we calculate in [link] . We discover that this ratio is a constant throughout the reaction. Therefore, therelationship between the rate of the reaction and the concentration of the reactant in this case is given by
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