Edward J. Neth; Paul Flowers; William R. Robinson, PhD; Klaus Theopold; Richard Langley

Learning Objectives

By the end of this section, you will be able to:

Distinguish net reactions from elementary reactions (steps)
Identify the molecularity of elementary reactions
Write a balanced chemical equation for a process given its reaction mechanism
Derive the rate law consistent with a given reaction mechanism

A balanced equation for a chemical reaction indicates what is reacting and what is produced, but it reveals nothing about how the reaction actually takes place. The reaction mechanism (or reaction path) is the process, or pathway, by which a reaction occurs.

A chemical reaction usually occurs in steps, although it may not always be obvious to an observer. The decomposition of ozone, for example, appears to follow a mechanism with two steps:

\begin{array}{l} O_{3} (g) ⟶ O_{2} (g) + O \\ O + O_{3} (g) ⟶ 2 O_{2} (g) \end{array}

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We call each step in a reaction mechanism an elementary reaction. Elementary reactions occur exactly as they are written and cannot be broken down into simpler steps. Elementary reactions add up to the overall reaction, which, for the decomposition, is:

2 O_{3} (g) ⟶ 3 O_{2} (g)

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Notice that the oxygen atom produced in the first step of this mechanism is consumed in the second step and therefore does not appear as a product in the overall reaction. Species that are produced in one step and consumed in a subsequent step are called intermediates.

While the overall reaction equation for the decomposition of ozone indicates that two molecules of ozone react to give three molecules of oxygen, the mechanism of the reaction does not involve the collision and reaction of two ozone molecules. Rather, it involves a molecule of ozone decomposing to an oxygen molecule and an intermediate oxygen atom; the oxygen atom then reacts with a second ozone molecule to give two oxygen molecules. These two elementary reactions occur exactly as they are shown in the reaction mechanism.

Unimolecular Elementary Reactions

The molecularity of an elementary reaction is the number of reactant species (atoms, molecules, or ions). For example, a unimolecular reaction involves the rearrangement of a single reactant species to produce one or more molecules of product:

A ⟶ products

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The rate equation for a unimolecular reaction is:

rate = k [A]

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A unimolecular reaction may be one of several elementary reactions in a complex mechanism. For example, the reaction:

O_{3} ⟶ O_{2} + O

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illustrates a unimolecular elementary reaction that occurs as one part of a two-step reaction mechanism. However, some unimolecular reactions may have only a single reaction in the reaction mechanism. (In other words, an elementary reaction can also be an overall reaction in some cases.) For example, the gas-phase decomposition of cyclobutane, C₄H₈, to ethylene, C₂H₄, occurs via a unimolecular, single-step mechanism:

In this figure, structural formulas are used to illustrate a chemical reaction. On the left, a structural formula for cyclobutane is shown. This structure is composed of 4 C atoms connected with single bonds in a square shape. Each C atom is bonded to two other C atoms in the structure, leaving two bonds for H atoms pointing outward above, below, left, and right. An arrow points right to two identical ethane molecules with a plus symbol between them. Each of these molecules contains two C atoms connected with a double bond oriented vertically between them. The C atom at the top of these molecules has H atoms bonded above to the right and left. Similarly, the lower C atom has two H atoms bonded below to the right and left.

For these unimolecular reactions to occur, all that is required is the separation of parts of single reactant molecules into products.

Chemical bonds do not simply fall apart during chemical reactions. Energy is required to break chemical bonds. The activation energy for the decomposition of C₄H₈, for example, is 261 kJ per mole. This means that it requires 261 kilojoules to distort one mole of these molecules into activated complexes that decompose into products:

In this figure, structural formulas are used to illustrate a chemical reaction, including an intermediate step. On the left, a structural formula for cyclobutane is shown. This structure is composed of 4 C atoms connected with single bonds in a square shape. Each C atom is bonded to two other C atoms in the structure, leaving two bonds for H atoms pointing outward above, below, left, and right. This structure is labeled, “Cyclohexane.” An arrow points right to a similar structure which has the upper and lower bonds replaced by rows of 4 dots. Similarly, columns of 3 dots appear just inside the line segments indicating the vertically oriented single bonds in the structure. The label “Activated complex” appears beneath this structure. A second arrow points right to two identical ethane molecules with a plus symbol between them. Each of these molecules contains two C atoms connected with a double bond oriented vertically between them. The C atom at the top of these molecules has H atoms bonded above to the right and left. Similarly, the lower C atom has two H atoms bonded below to the right and left. Below these two molecules appears the label “Ethylene.”

In a sample of C₄H₈, a few of the rapidly moving C₄H₈ molecules collide with other rapidly moving molecules and pick up additional energy. When the C₄H₈ molecules gain enough energy, they can transform into an activated complex, and the formation of ethylene molecules can occur. In effect, a particularly energetic collision knocks a C₄H₈ molecule into the geometry of the activated complex. However, only a small fraction of gas molecules travel at sufficiently high speeds with large enough kinetic energies to accomplish this. Hence, at any given moment, only a few molecules pick up enough energy from collisions to react.

The rate of decomposition of C₄H₈ is directly proportional to its concentration. Doubling the concentration of C₄H₈ in a sample gives twice as many molecules per liter. Although the fraction of molecules with enough energy to react remains the same, the total number of such molecules is twice as great. Consequently, there is twice as much C₄H₈ per liter, and the reaction rate is twice as fast:

rate = - \frac{Δ [C_{4} H_{8}]}{Δ t} = k [C_{4} H_{8}]

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A similar relationship applies to any unimolecular elementary reaction; the reaction rate is directly proportional to the concentration of the reactant, and the reaction exhibits first-order behavior. The proportionality constant is the rate constant for the particular unimolecular reaction.

Bimolecular Elementary Reactions

The collision and combination of two molecules or atoms to form an activated complex in an elementary reaction is called a bimolecular reaction. There are two types of bimolecular elementary reactions:

\begin{matrix} A + B ⟶ products \\ and \\ 2 A ⟶ products \end{matrix}

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For the first type, in which the two reactant molecules are different, the rate law is first-order in A and first order in B:

rate = k [A] [B]

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For the second type, in which two identical molecules collide and react, the rate law is second order in A:

rate = k [A] [A] = k [A]^{2}

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Some chemical reactions have mechanisms that consist of a single bimolecular elementary reaction. One example is the reaction of nitrogen dioxide with carbon monoxide:

{NO}_{2} (g) + CO (g) ⟶ NO (g) + {CO}_{2} (g)

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(see Figure 17.19)

This figure provides an illustration of a reaction between two H I molecules using space filling models. H atoms are shown as white spheres, and I atoms are shown as purple spheres. On the left, two H I molecules are shownwith a small white sphere bonded to a much larger purple sphere. The label, “Two H I molecules,” appears below. An arrow points right to a similar structure in which the two molecules appear pushed together, so that the purple spheres of the two molecules are touching. Below appears the label, “Transition state.” Following another arrow, two white spheres are shown vertically oriented and bonded together with the label, “H subscript 2” above. The H subscript 2 molecule is followed by a plus sign and two purple spheres bonded together with the label, “I subscript 2” above. Below these structures is the label, “Hydrogen iodide molecules decompose to produce hydrogen H subscript 2 and iodine I subscript 2.”

Figure 17.19 The probable mechanism for the reaction between NO₂ and CO to yield NO and CO₂.

Bimolecular elementary reactions may also be involved as steps in a multistep reaction mechanism. The reaction of atomic oxygen with ozone is one example:

O (g) + O_{3} (g) ⟶ {2O}_{2} (g)

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Termolecular Elementary Reactions

An elementary termolecular reaction involves the simultaneous collision of three atoms, molecules, or ions. Termolecular elementary reactions are uncommon because the probability of three particles colliding simultaneously is less than one one-thousandth of the probability of two particles colliding. There are, however, a few established termolecular elementary reactions. The reaction of nitric oxide with oxygen appears to involve termolecular steps:

\begin{array}{l} 2NO + O_{2} ⟶ 2 {NO}_{2} \\ rate = k {[NO]}^{2} [O_{2}] \end{array}

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Likewise, the reaction of nitric oxide with chlorine appears to involve termolecular steps:

\begin{array}{l} 2NO + {Cl}_{2} ⟶ 2 NOCl \\ rate = k {[NO]}^{2} [{Cl}_{2}] \end{array}

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Relating Reaction Mechanisms to Rate Laws

It's often the case that one step in a multistep reaction mechanism is significantly slower than the others. Because a reaction cannot proceed faster than its slowest step, this step will limit the rate at which the overall reaction occurs. The slowest step is therefore called the rate-limiting step (or rate-determining step) of the reaction Figure 17.20.

A photo is shown of cattle passing through a narrow chute into a holding pen. A person directs them through the gate with a long white and red pole.

Figure 17.20 A cattle chute is a nonchemical example of a rate-determining step. Cattle can only be moved from one holding pen to another as quickly as one animal can make its way through the chute. (credit: Loren Kerns)

As described earlier, rate laws may be derived directly from the chemical equations for elementary reactions. This is not the case, however, for ordinary chemical reactions. The balanced equations most often encountered represent the overall change for some chemical system, and very often this is the result of some multistep reaction mechanisms. In every case, we must determine the overall rate law from experimental data and deduce the mechanism from the rate law (and sometimes from other data). The reaction of NO₂ and CO provides an illustrative example:

{NO}_{2} (g) + CO (g) ⟶ {CO}_{2} (g) + NO (g)

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For temperatures above 225 °C, the rate law has been found to be:

rate = k [{NO}_{2}] [CO]

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The reaction is first order with respect to NO₂ and first-order with respect to CO. This is consistent with a single-step bimolecular mechanism and it is possible that this is the mechanism for this reaction at high temperatures.

At temperatures below 225 °C, the reaction is described by a rate law that is second order with respect to NO₂:

rate = k {[{NO}_{2}]}^{2}

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This is consistent with a mechanism that involves the following two elementary reactions, the first of which is slower and is therefore the rate-determining step:

\begin{array}{l} {NO}_{2} (g) + {NO}_{2} (g) ⟶ {NO}_{3} (g) + NO (g) (slow) \\ {NO}_{3} (g) + CO (g) ⟶ {NO}_{2} (g) + {CO}_{2} (g) (fast) \end{array}

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The rate-determining step gives a rate law showing second-order dependence on the NO₂ concentration, and the sum of the two equations gives the net overall reaction.

In general, when the rate-determining (slower) step is the first step in a mechanism, the rate law for the overall reaction is the same as the rate law for this step. However, when the rate-determining step is preceded by a step involving an equilibrium reaction, the rate law for the overall reaction may be more difficult to derive.

An elementary reaction is at equilibrium when it proceeds in both the forward and reverse directions at equal rates. Consider the dimerization of NO to N₂O₂, with k₁ used to represent the rate constant of the forward reaction and k_-1 used to represent the rate constant of the reverse reaction:

\begin{array}{l} NO + NO ⇌ N_{2} O_{2} \\ {rate}_{forward} = {rate}_{reverse} \\ k_{1} [NO]^{2} = k_{−1} [N_{2} O_{2}] \end{array}

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If N₂O₂ was an intermediate in a mechanism, this expression could be rearranged to represent the concentration of N₂O₂ in the overall rate law expression using algebraic manipulation:

(\frac{k_{1} [NO]^{2}}{k_{−1}}) = [N_{2} O_{2}]

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However, once again, intermediates cannot be listed as part of the overall rate law expression, though they can be included in an individual elementary reaction of a mechanism. Example 17.12 will illustrate how to derive overall rate laws from mechanisms involving equilibrium steps preceding the rate-determining step.

Example 17.12

Deriving the Overall Rate Law Expression for a Multistep Reaction Mechanism

Nitryl chloride (NO₂Cl) decomposes to nitrogen dioxide (NO₂) and chlorine gas (Cl₂) according to the following mechanism:

$2 {NO}_{2} Cl (g) ⇌ {ClO}_{2} (g) + N_{2} O (g) + ClO (g)$ (fast, k₁ represents the rate constant for the forward reaction and k₋₁ the rate constant for the reverse reaction)
$N_{2} O (g) + {ClO}_{2} (g) ⇌ {NO}_{2} (g) + NOCl (g)$ (fast, k₂ for the forward reaction, k₋₂ for the reverse reaction)
$NOCl + ClO ⟶ {NO}_{2} + {Cl}_{2}$ (slow, k₃ the rate constant for the forward reaction)

Determine the overall reaction, write the rate law expression for each elementary reaction, identify any intermediates, and determine the overall rate law expression.

Solution

For the overall reaction, simply sum the three steps, cancel intermediates, and combine like formulas:

{2NO}_{2} Cl (g) ⟶ 2 {NO}_{2} (g) + {Cl}_{2} (g)

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Next, write the rate law expression for each elementary reaction. Remember that for elementary reactions that are part of a mechanism, the rate law expression can be derived directly from the stoichiometry:

\begin{matrix} k_{1} {[{NO}_{2} Cl]}_{2} & = & k_{−1} [{ClO}_{2}] [N_{2} O] [ClO] \\ k_{2} [N_{2} O] [{ClO}_{2}] & = & k_{−2} [{NO}_{2}] [NOCl] \\ Rate & = & k_{3} [NOCl] [ClO] \end{matrix}

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The third step, which is the slow step, is the rate-determining step. Therefore, the overall rate law expression could be written as Rate = k₃ [NOCl][ClO]. However, both NOCl and ClO are intermediates. Algebraic expressions must be used to represent [NOCl] and [ClO] such that no intermediates remain in the overall rate law expression.

Using elementary reaction 1, $[ClO] = \frac{k_{1} {[{NO}_{2} Cl]}^{2}}{k_{- 1} [{ClO}_{2}] [N_{2} O]} .$

Using elementary reaction 2, $[NOCl] = \frac{k_{2} [N_{2} O] [{ClO}_{2}]}{k_{−2} [{NO}_{2}]} .$

Now substitute these algebraic expressions into the overall rate law expression and simplify:

\begin{matrix} rate & = & k_{3} (\frac{k_{2} [N_{2} O] [{ClO}_{2}]}{k_{- 2} [{NO}_{2}]}) (\frac{k_{1} {[{NO}_{2} Cl]}^{2}}{k_{- 1} [{ClO}_{2}] [N_{2} O]}) \\ rate & = & \frac{k_{3} k_{2} k_{1} {[{NO}_{2} Cl]}^{2}}{k_{- 2} k_{- 1} [{NO}_{2}]} \end{matrix}

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Notice that this rate law shows an inverse dependence on the concentration of one of the product species, consistent with the presence of an equilibrium step in the reaction mechanism.

Check Your Learning

Atomic chlorine in the atmosphere reacts with ozone in the following pair of elementary reactions:

Cl + O_{3} (g) ⟶ ClO (g) + O_{2} (g) (rate constant k_{1})

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ClO (g) + O ⟶ Cl (g) + O_{2} (g) (rate constant k_{2})

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