12-5: Reaction Mechanism

Author:Anda Toshiki

Updated:3 months ago

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12-5-1: Learning Objectives

Learning Objectives

One of the major reasons for studying chemical kinetics is to use measurements of the macroscopic properties of a system, such as the rate of change in the concentration of reactants or products with time, to discover the sequence of events that occur at the molecular level during a reaction. This molecular description is the mechanism of the reaction; it describes how individual atoms, ions, or molecules interact to form particular products. The stepwise changes are collectively called the reaction mechanism.

In an internal combustion engine, for example, isooctane reacts with oxygen to give carbon dioxide and water:

2 \mathrm{C}_{8} \mathrm{H}_{18}(\mathrm{l})+25 \mathrm{O}_{2}(\mathrm{~g}) \longrightarrow 16 \mathrm{CO}_{2}(\mathrm{~g})+18 \mathrm{H}_{2} \mathrm{O}(\mathrm{g})

For this reaction to occur in a single step, 25 dioxygen molecules and 2 isooctane molecules would have to collide simultaneously and be converted to 34 molecules of product, which is very unlikely. It is more likely that a complex series of reactions takes place in a stepwise fashion. Each individual reaction, which is called an elementary reaction, involves one, two, or (rarely) three atoms, molecules, or ions. The overall sequence of elementary reactions is the mechanism of the reaction. The sum of the individual steps, or elementary reactions, in the mechanism must give the balanced chemical equation for the overall reaction.

The overall sequence of elementary reactions is the mechanism of the reaction.

12-5-2: Molecularity and the Rate-Determining Step

To demonstrate how the analysis of elementary reactions helps us determine the overall reaction mechanism, we will examine the much simpler reaction of carbon monoxide with nitrogen dioxide.

\mathrm{2CO + 2NO_2 \rightarrow 2CO_2 + N_2O_4}

From the balanced chemical equation, one might expect the reaction to occur via a collision of one molecule of $\mathrm{NO}_{2}$ with a molecule of $\mathrm{CO}$ that results in the transfer of an oxygen atom from nitrogen to carbon. The experimentally determined rate law for the reaction, however, is as follows:

\text { rate }=k\left[\mathrm{NO}_{2}\right]^{2}

The fact that the reaction is second order in $\left[\mathrm{NO}_{2}\right]$ and independent of $[\mathrm{CO}]$ tells us that it does not occur by the simple collision model outlined previously. If it did, its predicted rate law would be

\text { rate }=k\left[\mathrm{NO}_{2}\right][\mathrm{CO}] .

The following two-step mechanism is consistent with the rate law if step 1 is much slower than step 2:

15-2-1: Two-Step Mechanism

Steps	Reaction	Reaction Type
step 1	$\mathrm{NO}_{2}+\mathrm{NO}_{2} \stackrel{\text { slow }}{\longrightarrow} \mathrm{NO}_{3}+\mathrm{NO}$	elementary reaction
step 2	$\underline{\mathrm{NO}_{3}+\mathrm{CO} \rightarrow \mathrm{NO}_{2}+\mathrm{CO}_{2}}$	elementary reaction
sum	$\mathrm{NO}_{2}+\mathrm{CO} \rightarrow \mathrm{NO}+\mathrm{CO}_{2}$	overall reaction

According to this mechanism, the overall reaction occurs in two steps, or elementary reactions. Summing steps 1 and 2 and canceling on both sides of the equation gives the overall balanced chemical equation for the reaction. The $\mathrm{NO_3}$ molecule is intermediate in the reaction, a species that does not appear in the balanced chemical equation for the overall reaction. It is formed as a product of the first step but is consumed in the second step.

The sum of the elementary reactions in a reaction mechanism must give the overall balanced chemical equation of the reaction.

12-5-3: Using Molecularity to Describe a Rate Law

The molecularity of an elementary reaction is the number of molecules that collide during that step in the mechanism. If there is only a single reactant molecule in an elementary reaction, that step is designated as unimolecular; if there are two reactant molecules, it is bimolecular; and if there are three reactant molecules (a relatively rare situation), it is termolecular. Elementary reactions that involve the simultaneous collision of more than three molecules are highly improbable and have never been observed experimentally. (To understand why, try to make three or more marbles or pool balls collide with one another simultaneously!)

About the image

The Basis for Writing Rate Laws of Elementary Reactions. This diagram illustrates how the number of possible collisions per unit time between two reactant species, A and B, depends on the number of A and B particles present. The number of collisions between A and B particles increases as the product of the number of particles, not as the sum. This is why the rate law for an elementary reaction depends on the product of the concentrations of the species that collide in that step. (CC BY-NC-SA; anonymous)

Writing the rate law for an elementary reaction is straightforward because we know how many molecules must collide simultaneously for the elementary reaction to occur; hence the order of the elementary reaction is the same as its molecularity (Table 14.6.1). In contrast, the rate law for the reaction cannot be determined from the balanced chemical equation for the overall reaction. The general rate law for a unimolecular elementary reaction ( $\mathrm{A} \rightarrow$ products) is

\text { rate }=k[A] .

For bimolecular reactions, the reaction rate depends on the number of collisions per unit time, which is proportional to the product of the concentrations of the reactants, as shown in Figure 14.6.1 For a bimolecular elementary reaction of the form $\mathrm{A}+\mathrm{B} \rightarrow$ products, the general rate law is

\text { rate }=k[A][B] .

Elementary Reaction	Molecularity	Rate	Reaction Order
$\mathrm{A} \rightarrow \text { products }$	Unimolecular	$\text { rate }=k[\mathrm{~A}]$	first
$2\mathrm{~A} \rightarrow \text { products }$	Bimolecular	$\text { rate }=k[\mathrm{~A}]^2$	second
$\mathrm{A}+\mathrm{B} \rightarrow \text { products }$	Bimolecular	$\text { rate }=k[\mathrm{~A}][\mathrm{B}]$	second
$2 \mathrm{~A}+\mathrm{B} \rightarrow \text { products }$	Termolecular	$\text { rate }=k[\mathrm{~A}]^2[\mathrm{~B}]$	third
$\mathrm{A}+\mathrm{B}+\mathrm{C} \rightarrow \text { products }$	Termolecular	$\text { rate }=k[\mathrm{~A}][\mathrm{B}][\mathrm{C}]$	third

For elementary reactions, the order of the elementary reaction is the same as its molecularity. In contrast, the rate law cannot be determined from the balanced chemical equation for the overall reaction (unless it is a single step mechanism and is therefore also an elementary step).

12-5-4: Identifying the Rate-Determining Step

Note the important difference between writing rate laws for elementary reactions and the balanced chemical equation of the overall reaction. Because the balanced chemical equation does not necessarily reveal the individual elementary reactions by which the reaction occurs, we cannot obtain the rate law for a reaction from the overall balanced chemical equation alone. In fact, it is the rate law for the slowest overall reaction, which is the same as the rate law for the slowest step in the reaction mechanism, the ratedetermining step, that must give the experimentally determined rate law for the overall reaction.This statement is true if one step is substantially slower than all the others, typically by a factor of 10 or more. If two or more slow steps have comparable rates, the experimentally determined rate laws can become complex. Our discussion is limited to reactions in which one step can be identified as being substantially slower than any other. The reason for this is that any process that occurs through a sequence of steps can take place no faster than the slowest step in the sequence. In an automotive assembly line, for example, a component cannot be used faster than it is produced. Similarly, blood pressure is regulated by the flow of blood through the smallest passages, the capillaries. Because movement through capillaries constitutes the rate-determining step in blood flow, blood pressure can be regulated by medications that cause the capillaries to contract or dilate. A chemical reaction that occurs via a series of elementary reactions can take place no faster than the slowest step in the series of reactions.

Look at the rate laws for each elementary reaction in the example as well as for the overall reaction.

Rate laws for each elementary reaction in our example as well as for the overall reaction

Steps	Reaction	Rate
step 1	$\mathrm{NO}_2+\mathrm{NO}_2 \stackrel{\mathrm{k}_1}{\rightarrow} \mathrm{NO}_3+\mathrm{NO}$	$\text { rate }=k_1\left[\mathrm{NO}_2\right]^2(\text { predicted) }$
step 2	$\underline{\mathrm{NO}_3+\mathrm{CO} \stackrel{k_2}{\rightarrow} \mathrm{NO}_2+\mathrm{CO}_2}$	$\text { rate }=k_2\left[\mathrm{NO}_3\right][\mathrm{CO}](\text { predicted })$
step 3	$\mathrm{NO}_2+\mathrm{CO} \stackrel{k}{\rightarrow} \mathrm{NO}+\mathrm{CO}_2$	$\text { rate }=k\left[\mathrm{NO}_2\right]^2(\text { observed) }$

The experimentally determined rate law for the reaction of $\mathrm{NO}_{2}$ with $C O$ is the same as the predicted rate law for step 1 . This tells us that the first elementary reaction is the rate-determining step, so $k$ for the overall reaction must equal $k_{1}$ . That is, $\mathrm{NO}_{3}$ is formed slowly in step 1, but once it is formed, it reacts very rapidly with CO in step 2.

Sometimes chemists are able to propose two or more mechanisms that are consistent with the available data. If a proposed mechanism predicts the wrong experimental rate law, however, the mechanism must be incorrect.

12-5-4-1: Example-A Reaction with an Intermediate

In an alternative mechanism for the reaction of $\mathrm{NO}_{2}$ with $\mathrm{CO}$ with $\mathrm{N}_{2} \mathrm{O}_{4}$ appearing as an intermediate.

alternative mechanism for the reaction of $\mathrm{NO}_{2}$ with $\mathrm{CO}$ with $\mathrm{N}_{2} \mathrm{O}_{4}$ appearing as an intermediate.

Write the rate law for each elementary reaction. Is this mechanism consistent with the experimentally determined rate law (rate $=\mathrm{k[{NO}_{2}]^{2}t}$ )

Given: elementary reactions Asked for: rate law for each elementary reaction and overall rate law

Strategy

Determine the rate law for each elementary reaction in the reaction.
Determine which rate law corresponds to the experimentally determined rate law for the reaction. This rate law is the one for the rate-determining step.

Solution

View solution

A The rate law for step 1 is rate $=k_{1}\left[\mathrm{NO}_{2}\right]^{2}$ ; for step 2 , it is rate $=k_{2}\left[\mathrm{~N}_{2} \mathrm{O}_{4}\right][\mathrm{CO}]$ .

B If step 1 is slow (and therefore the rate-determining step), then the overall rate law for the reaction will be the same: rate $=$ $k_{1}\left[\mathrm{NO}_{2}\right]^{2}$ . This is the same as the experimentally determined rate law. Hence this mechanism, with $\mathrm{N}_{2} \mathrm{O}_{4}$ as an intermediate, and the one described previously, with $\mathrm{NO}_{3}$ as an intermediate, are kinetically indistinguishable. In this case, further experiments are needed to distinguish between them. For example, the researcher could try to detect the proposed intermediates, $\mathrm{NO}_{3}$ and $\mathrm{N}_{2} \mathrm{O}_{4}$ , directly.

12-5: Reaction Mechanism ​

12-5-1: Learning Objectives ​

12-5-2: Molecularity and the Rate-Determining Step ​

15-2-1: Two-Step Mechanism ​

12-5-3: Using Molecularity to Describe a Rate Law ​

12-5-4: Identifying the Rate-Determining Step ​

12-5-4-1: Example-A Reaction with an Intermediate ​

Strategy ​

Solution ​