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Chapter 19: Problem 54

A chemist studied the reaction mechanism for the reaction $$ 2 \mathrm{NO}(g)+\mathrm{O}_{2}(g) \longrightarrow 2 \mathrm{NO}_{2}(g) $$ by reacting \(\mathrm{N}^{16} \mathrm{O}\) with \({ }^{18} \mathrm{O}_{2}\). If the reaction mechanism is $$ \begin{aligned} \mathrm{NO}+\mathrm{O}_{2} & \rightleftharpoons \mathrm{NO}_{3}(\text { fast equilibrium }) \\ \mathrm{NO}_{3}+\mathrm{NO} \longrightarrow 2 \mathrm{NO}_{2}(\text { slow }) \end{aligned} $$ what distribution of \({ }^{18} \mathrm{O}\) would you expect in the \(\mathrm{NO}_{2}\) ? Assume that \(\mathrm{N}\) is the central atom in \(\mathrm{NO}_{3}\), assume only \(\mathrm{N}^{16} \mathrm{O}^{18} \mathrm{O}_{2}\) forms, and assume stoichiometric amounts of reactants are combined.

Short Answer

Expert verified
The distribution of \(^{18}O\) in the \(NO_2\) molecules will be approximately 50%, as half of the produced \(NO_2\) molecules will contain \(^{18}O\) and the other half will hold \(^{16}O\).

Step by step solution

01

Understand the reaction mechanism

Given the mechanism in the problem, it happens in two steps. In the first step, the reaction between \(NO\) and \(O_2\) forms \(NO_3\). Then, the \(NO_3\) reacts with another \(NO\) molecule to produce 2 \(NO_2\) molecules. The given mechanism can be summarized as follows: \begin{aligned} N^{16}O+^{18}O_{2} &\rightleftharpoons N^{16}O^{18}O_2 (\text{fast equilibrium}) \\ N^{16}O^{18}O_2 + N^{16}O &\longrightarrow 2 NO_2(\text{slow}) \end{aligned}
02

Form the possible \(NO_2\) products

Knowing that \(N\) is the central atom in \(NO_3\), we can expect that the oxygen atoms can exchange with the other oxygen atoms in the reaction. Let's write down the possible \(NO_2\) products: 1. \(N^{16}O^{18}O\): When \(NO_3\) loses one \(^{18}O\) and forms \(NO_2\), 2. \(N^{16}O^{16}O\): When \(NO_3\) loses one \(^{16}O\) and forms \(NO_2\).
03

Analyze the stoichiometry of the reaction

The given balanced reaction has stoichiometric coefficients: $$ 2\text{ } NO(g) + O_{2}(g) \longrightarrow 2 \text{ } NO_{2}(g) $$ Since we are assuming the reactants are combined in stoichiometric amounts, we can expect that after the reaction reaches equilibrium, we will have roughly equal amounts of \(N^{16}O^{18}O\) and \(N^{16}O^{16}O\) in the final products.
04

Determine the distribution of \(^{18}O\) in the \(NO_2\)

Since we are using stoichiometric amounts of reactants, we will have equal concentrations of \(N^{16}O^{18}O\) and \(N^{16}O^{16}O\) in the final products. Because the \(^{18}O\) is distributed between two \(NO_2\) molecules, half of the produced \(NO_2\) molecules will contain \(^{18}O\), and the other half will hold \(^{16}O\). Therefore, the distribution of \(^{18}O\) in \(NO_2\) will be approximately 50%.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Understanding Chemical Kinetics
Chemical kinetics is the study of reaction rates, how quickly reactions occur, and the factors that affect these rates. When studying chemical reactions, understanding the mechanism—a step-by-step sequence of elementary reactions by which the overall chemical change occurs—is crucial. A mechanism describes the exact process and order in which bonds are broken and formed, and how reactive intermediates, such as free radicals or complexes, are involved.

In the study of the reaction between nitrogen monoxide (o2) and oxygen (o2), the chemist is specifically looking at how these gases interact to produce nitrogen dioxide (o2). Here, kinetics plays a key role in identifying the 'fast' initial reaction establishing a quick equilibrium between o and o2, forming o3, and the 'slow', rate-determining step where o3 reacts with another o molecule to form the final product, o2. The rate at which these steps occur helps in understanding the reaction mechanism. It is the slowest step in this sequence that determines the overall reaction rate, thus underlining the importance of chemical kinetics in the study of reaction mechanisms.
The Role of Isotopic Labeling
Isotopic labeling is a technique used to track the movement of atoms through a reaction mechanism. By replacing a common isotope of an element with a detectable one, chemists can ascertain the fate of atoms in the products. This is particularly useful in complex reactions where multiple pathways and intermediates are involved.

In the given reaction, isotopic labeling involves the use of o and o2, where the oxygen-18 (o) isotope is used as a tracer. Since oxygen generally forms two bonds, the labeled oxygen from o2 can incorporate into the intermediates and final products. By examining the distribution of o in the final nitrogen dioxide molecules, one can confirm the pathway predicted by the proposed mechanism. This hands-on confirmation using isotopic labeling displays the powerful interplay between experimental techniques and theoretical predictions in understanding chemical processes.
Stoichiometry in Reaction Mechanisms
Stoichiometry is the calculation of the quantities of reactants and products in chemical reactions. In a chemical equation, the stoichiometric coefficients represent the number of moles of each substance that react to form the products. It is essential for predicting the quantities of products formed and the amount of reactants needed.

In the context of the given problem where nitrogen monoxide reacts with oxygen to form nitrogen dioxide, stoichiometry dictates that two moles of o will react with one mole of o2 to produce two moles of o2, based on the balanced chemical equation. When the reaction proceeds under stoichiometric conditions—that is, the reactants are combined in the exact ratios as depicted by the balanced equation—we can predict the amounts of each possible product, which is vital for interpreting results such as the distribution of isotopes in the products. Stoichiometry, in this case, assures us that if the reaction goes to completion under the given conditions, we should expect equal amounts of the two different isotopologues of o2, thereby giving a 50% distribution of the o isotope among the o2 molecules.

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Most popular questions from this chapter

The sun radiates \(3.9 \times 10^{23} \mathrm{~J}\) of energy into space every \(\mathrm{sec}-\) ond. What is the rate at which mass is lost from the sun?

Radioactive cobalt-60 is used to study defects in vitamin \(\mathrm{B}_{12}\) absorption because cobalt is the metallic atom at the center of the vitamin \(\mathrm{B}_{12}\) molecule. The nuclear synthesis of this cobalt isotope involves a three-step process. The overall reaction is iron- 58 reacting with two neutrons to produce cobalt-60 along with the emission of another particle. What particle is emitted in this nuclear synthesis? What is the binding energy in J per nucleon for the cobalt-60 nucleus (atomic masses: \({ }^{60} \mathrm{Co}=\) 59.9338 u; \({ }^{1} \mathrm{H}=1.00782 \mathrm{u}\) )? What is the de Broglie wavelength of the emitted particle if it has a velocity equal to \(0.90 c\), where \(c\) is the speed of light?

The most significant source of natural radiation is radon- 222 . \({ }^{222} \mathrm{Rn}\), a decay product of \({ }^{238} \mathrm{U}\), is continuously generated in the earth's crust, allowing gaseous \(\mathrm{Rn}\) to seep into the basements of buildings. Because \({ }^{222} \mathrm{Rn}\) is an \(\alpha\) -particle producer with a relatively short half-life of \(3.82\) days, it can cause biological damage when inhaled. a. How many \(\alpha\) particles and \(\beta\) particles are produced when \({ }^{238} \mathrm{U}\) decays to \({ }^{222} \mathrm{Rn}\) ? What nuclei are produced when 222 \(\mathrm{Rn}\) decays? b. Radon is a noble gas so one would expect it to pass through the body quickly. Why is there a concern over inhaling \({ }^{222} \mathrm{Rn}\) ? c. Another problem associated with \({ }^{222} \mathrm{Rn}\) is that the decay of \({ }^{222} \mathrm{Rn}\) produces a more potent \(\alpha\) -particle producer \(\left(t_{1 / 2}=\right.\) \(3.11 \mathrm{~min}\) ) that is a solid. What is the identity of the solid? Give the balanced equation of this species decaying by \(\alpha\) -particle production. Why is the solid a more potent \(\alpha\) -particle producer? d. The U.S. Environmental Protection Agency (EPA) recommends that \({ }^{222} \mathrm{Rn}\) levels not exceed 4 pCi per liter of air \(\left(1 \mathrm{Ci}=1\right.\) curie \(=3.7 \times 10^{10}\) decay events per second; \(\left.1 \mathrm{pCi}=1 \times 10^{-12} \mathrm{Ci}\right) .\) Convert \(4.0 \mathrm{pCi}\) per liter of air into concentrations units of \({ }^{222} \mathrm{Rn}\) atoms per liter of air and moles of \(222 \mathrm{Rn}\) per liter of air.

Strontium-90 and radon-222 both pose serious health risks. \({ }^{90} \mathrm{Sr}\) decays by \(\beta\) -particle production and has a relatively long half-life (28.9 years). Radon-222 decays by \(\alpha\) -particle production and has a relatively short half-life (3.82 days). Explain why each decay process poses health risks.

Rubidium- 87 decays by \(\beta\) -particle production to strontium- 87 with a half-life of \(4.7 \times 10^{10}\) years. What is the age of a rock sample that contains \(109.7 \mu \mathrm{g}\) of \({ }^{87} \mathrm{Rb}\) and \(3.1 \mu \mathrm{g}\) of \({ }^{87} \mathrm{Sr}\) ? Assume that no \({ }^{87} \mathrm{Sr}\) was present when the rock was formed. The atomic masses for \({ }^{87} \mathrm{Rb}\) and \({ }^{87} \mathrm{Sr}\) are \(86.90919 \mathrm{u}\) and \(86.90888\) u, respectively.
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