Using Graphs to Determine Rate Laws, Rate Constants, and Reaction Orders

14.4 Using Graphs to Determine Rate Laws, Rate Constants, and Reaction Orders

Learning Objective

To use graphs to analyze the kinetics of a reaction.

In Section 14.3 "Methods of Determining Reaction Order", you learned that the integrated rate law for each common type of reaction (zeroth, first, or second order in a single reactant) can be plotted as a straight line. Using these plots offers an alternative to the methods described for showing how reactant concentration changes with time and determining reaction order.

We will illustrate the use of these graphs by considering the thermal decomposition of NO₂ gas at elevated temperatures, which occurs according to the following reaction:

Equation 14.26

2 {NO}_{2} (g) \overset{Δ}{\to} 2 NO(g) + O_{2} (g)

Experimental data for this reaction at 330°C are listed in Table 14.5 "Concentration of NO"; they are provided as [NO₂], ln[NO₂], and 1/[NO₂] versus time to correspond to the integrated rate laws for zeroth-, first-, and second-order reactions, respectively. The actual concentrations of NO₂ are plotted versus time in part (a) in Figure 14.15 "The Decomposition of NO". Because the plot of [NO₂] versus t is not a straight line, we know the reaction is not zeroth order in NO₂. A plot of ln[NO₂] versus t (part (b) in Figure 14.15 "The Decomposition of NO") shows us that the reaction is not first order in NO₂ because a first-order reaction would give a straight line. Having eliminated zeroth-order and first-order behavior, we construct a plot of 1/[NO₂] versus t (part (c) in Figure 14.15 "The Decomposition of NO"). This plot is a straight line, indicating that the reaction is second order in NO₂.

Table 14.5 Concentration of NO₂ as a Function of Time at 330°C

Time (s)	[NO₂] (M)	ln[NO₂]	1/[NO₂] (M⁻¹)
0	1.00 × 10⁻²	−4.605	100
60	6.83 × 10⁻³	−4.986	146
120	5.18 × 10⁻³	−5.263	193
180	4.18 × 10⁻³	−5.477	239
240	3.50 × 10⁻³	−5.655	286
300	3.01 × 10⁻³	−5.806	332
360	2.64 × 10⁻³	−5.937	379

Figure 14.15 The Decomposition of NO₂

These plots show the decomposition of a sample of NO₂ at 330°C as (a) the concentration of NO₂ versus t, (b) the natural logarithm of [NO₂] versus t, and (c) 1/[NO₂] versus t.

We have just determined the reaction order using data from a single experiment by plotting the concentration of the reactant as a function of time. Because of the characteristic shapes of the lines shown in Figure 14.16 "Properties of Reactions That Obey Zeroth-, First-, and Second-Order Rate Laws", the graphs can be used to determine the reaction order of an unknown reaction. In contrast, the method described in Section 14.3 "Methods of Determining Reaction Order" required multiple experiments at different NO₂ concentrations as well as accurate initial rates of reaction, which can be difficult to obtain for rapid reactions.

Figure 14.16 Properties of Reactions That Obey Zeroth-, First-, and Second-Order Rate Laws

Example 9

Dinitrogen pentoxide (N₂O₅) decomposes to NO₂ and O₂ at relatively low temperatures in the following reaction:

2N₂O₅(soln) → 4NO₂(soln) + O₂(g)

This reaction is carried out in a CCl₄ solution at 45°C. The concentrations of N₂O₅ as a function of time are listed in the following table, together with the natural logarithms and reciprocal N₂O₅ concentrations. Plot a graph of the concentration versus t, ln concentration versus t, and 1/concentration versus t and then determine the rate law and calculate the rate constant.

Time (s)	[N₂O₅] (M)	ln[N₂O₅]	1/[N₂O₅] (M⁻¹)
0	0.0365	−3.310	27.4
600	0.0274	−3.597	36.5
1200	0.0206	−3.882	48.5
1800	0.0157	−4.154	63.7
2400	0.0117	−4.448	85.5
3000	0.00860	−4.756	116
3600	0.00640	−5.051	156

Given: balanced chemical equation, reaction times, and concentrations

Asked for: graph of data, rate law, and rate constant

Strategy:

A Use the data in the table to separately plot concentration, the natural logarithm of the concentration, and the reciprocal of the concentration (the vertical axis) versus time (the horizontal axis). Compare the graphs with those in Figure 14.16 "Properties of Reactions That Obey Zeroth-, First-, and Second-Order Rate Laws" to determine the reaction order.

B Write the rate law for the reaction. Using the appropriate data from the table and the linear graph corresponding to the rate law for the reaction, calculate the slope of the plotted line to obtain the rate constant for the reaction.

Solution:

A Here are plots of [N₂O₅] versus t, ln[N₂O₅] versus t, and 1/[N₂O₅] versus t:

The plot of ln[N₂O₅] versus t gives a straight line, whereas the plots of [N₂O₅] versus t and 1/[N₂O₅] versus t do not. This means that the decomposition of N₂O₅ is first order in [N₂O₅].

B The rate law for the reaction is therefore

rate = k[N₂O₅]

Calculating the rate constant is straightforward because we know that the slope of the plot of ln[A] versus t for a first-order reaction is −k. We can calculate the slope using any two points that lie on the line in the plot of ln[N₂O₅] versus t. Using the points for t = 0 and 3000 s,

slope = \frac{\ln {[N_{2} O_{5}]}_{3000} - \ln {[N_{2} O_{5}]}_{0}}{3000 s - 0 s} = \frac{(- 4.756) - (- 3.310)}{3000 s} = - 4.820 \times 10^{- 4} s^{- 1}

Thus k = 4.820 × 10⁻⁴ s⁻¹.

Exercise

1,3-Butadiene (CH₂=CH—CH=CH_2; C₄H₆) is a volatile and reactive organic molecule used in the production of rubber. Above room temperature, it reacts slowly to form products. Concentrations of C₄H₆ as a function of time at 326°C are listed in the following table along with ln[C₄H₆] and the reciprocal concentrations. Graph the data as concentration versus t, ln concentration versus t, and 1/concentration versus t. Then determine the reaction order in C₄H₆, the rate law, and the rate constant for the reaction.

Time (s)	[C₄H₆] (M)	ln[C₄H₆]	1/[C₄H₆] (M⁻¹)
0	1.72 × 10⁻²	−4.063	58.1
900	1.43 × 10⁻²	−4.247	69.9
1800	1.23 × 10⁻²	−4.398	81.3
3600	9.52 × 10⁻³	−4.654	105
6000	7.30 × 10⁻³	−4.920	137

Answer:

second order in C₄H₆; rate = k[C₄H₆]²; k = 1.3 × 10⁻² M⁻¹·s⁻¹

Summary

For a zeroth-order reaction, a plot of the concentration of any reactant versus time is a straight line with a slope of −k. For a first-order reaction, a plot of the natural logarithm of the concentration of a reactant versus time is a straight line with a slope of −k. For a second-order reaction, a plot of the inverse of the concentration of a reactant versus time is a straight line with a slope of k.

Key Takeaway

Plotting the concentration of a reactant as a function of time produces a graph with a characteristic shape that can be used to identify the reaction order in that reactant.

Conceptual Problems

Compare first-order differential and integrated rate laws with respect to the following. Is there any information that can be obtained from the integrated rate law that cannot be obtained from the differential rate law?
1. the magnitude of the rate constant
2. the information needed to determine the order
3. the shape of the graphs
In the single-step, second-order reaction 2A → products, how would a graph of [A] versus time compare to a plot of 1/[A] versus time? Which of these would be the most similar to the same set of graphs for A during the single-step, second-order reaction A + B → products? Explain.
For reactions of the same order, what is the relationship between the magnitude of the rate constant and the reaction rate? If you were comparing reactions with different orders, could the same arguments be made? Why?

Answers

1. For a given reaction under particular conditions, the magnitude of the first-order rate constant does not depend on whether a differential rate law or an integrated rate law is used.
2. The differential rate law requires multiple experiments to determine reactant order; the integrated rate law needs only one experiment.
3. Using the differential rate law, a graph of concentration versus time is a curve with a slope that becomes less negative with time, whereas for the integrated rate law, a graph of ln[reactant] versus time gives a straight line with slope = −k. The integrated rate law allows you to calculate the concentration of a reactant at any time during the reaction; the differential rate law does not.
The reaction rate increases as the rate constant increases. We cannot directly compare reaction rates and rate constants for reactions of different orders because they are not mathematically equivalent.

Numerical Problems

One method of using graphs to determine reaction order is to use relative rate information. Plotting the log of the relative rate versus log of relative concentration provides information about the reaction. Here is an example of data from a zeroth-order reaction:

Relative [A] (M)	Relative Rate (M/s)
1	1
2	1
3	1

Varying [A] does not alter the reaction rate. Using the relative rates in the table, generate plots of log(rate) versus log(concentration) for zeroth-, first- and second-order reactions. What does the slope of each line represent?

The table below follows the decomposition of N₂O₅ gas by examining the partial pressure of the gas as a function of time at 45°C. What is the reaction order? What is the rate constant? How long would it take for the pressure to reach 105 mmHg at 45°C?

Time (s)	Pressure (mmHg)
0	348
400	276
1600	156
3200	69
4800	33