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Chapter 14: Problem 21

In the first-order reaction \(A \longrightarrow\) products, it is found that \(99 \%\) of the original amount of reactant \(A\) decomposes in 137 min. What is the half-life, \(t_{1 / 2}\), of this decomposition reaction?

Short Answer

Expert verified
The half-life for this first order decomposition reaction is \(t_{1/2} = \frac{0.693 * 137}{ln(100)}\) minutes

Step by step solution

01

Find Rate Constant k

First, calculate the rate constant, k, using the equation for first order reactions \(k = \frac{ln[N_0 / N]}{t}\). Here, [N_0] is the initial concentration and [N] the final concentration. Since it is stated that 99% of A has decomposed, the remaining is 1%. So, [N] = 0.01[N_0]. This simplifies to \(k = \frac{ln(100)}{137}\)
02

Calculate Half Life

Substitute k into the formula for half-life of a first-order reaction \(t_{1/2} = \frac{0.693}{k}\). After substituting you will get \(t_{1/2} = \frac{0.693}{\frac{ln(100)}{137}}\)
03

Simplify the expression

Finally, simplify the expression to find \(t_{1/2}\). The final result after simplification will be the half life time of the reaction.

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Key Concepts

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

Understanding the Rate Constant in First-Order Reactions
In the context of first-order reactions, the rate constant, often represented by the symbol \(k\), is a crucial parameter. It can be understood as a measure of how quickly the reactants are transformed into products. The rate constant is derived from the rate law specific to first-order reactions. This relationship is given by the equation:
\[ k = \frac{ln[N_0 / N]}{t} \]
Where:
  • \([N_0]\) represents the initial concentration of the reactant
  • \([N]\) is the concentration of the reactant at time \(t\)
  • \(t\) is the time elapsed

In practical terms, once you know how much of the reactant remains at a certain time, you can calculate \(k\). For example, if only 1% of the original reactant remains, as it occurs in the problem, you can set \([N]\) to 0.01\([N_0]\), and solve for \(k\).
Mastering Half-Life Calculation for First-Order Reactions
The half-life of a reaction, symbolized as \(t_{1/2}\), is the time it takes for half of the original amount of reactant to decompose. In first-order reactions, the half-life is independent of the initial concentration, making it a convenient characteristic value to calculate. The formula to find the half-life in a first-order reaction is:
\[ t_{1/2} = \frac{0.693}{k} \]
This equation shows that \(t_{1/2}\) is inversely proportional to the rate constant \(k\). Thus, a larger \(k\) indicates a quicker reaction and a shorter \(t_{1/2}\).
After calculating \(k\) using the specific conditions provided in the problem (in this case, when 99% decomposition occurs), you can apply this formula for \(t_{1/2}\). This straightforward approach provides insight into how quickly the reaction progresses over time.
The Nature of Decomposition Reactions
Decomposition reactions are fascinating chemical processes where a single compound breaks down into two or more simpler substances. These reactions are commonly found in various scientific and industrial fields. In the case of a first-order decomposition reaction, like the one described, the reaction rate depends solely on the concentration of the decaying substance.
The reaction of compound \(A\) decomposing can be depicted simply as \(A \longrightarrow \text{products}\).
This illustrates that as \(A\) gets consumed, its decrease in concentration causes the reaction to continue at a predictable pace determined by the rate constant \(k\).
Such reactions are pivotal because they allow scientists and engineers to predict how fast a substance will disappear under certain conditions, which is invaluable in waste management, pollution control, and even in everyday household chores.

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Most popular questions from this chapter

For the reaction \(A+2 B \longrightarrow 2 C\), the rate of reaction is \(1.76 \times 10^{-5} \mathrm{M} \mathrm{s}^{-1}\) at the time when \([\mathrm{A}]=0.3580 \mathrm{M}.\) (a) What is the rate of formation of \(\mathrm{C}\) ? (b) What will \([\mathrm{A}]\) be 1.00 min later? (c) Assume the rate remains at \(1.76 \times 10^{-5} \mathrm{M} \mathrm{s}^{-1}\) How long would it take for \([\mathrm{A}]\) to change from 0.3580 to \(0.3500 \mathrm{M} ?\)

You want to test the following proposed mechanism for the oxidation of HBr. $$\begin{array}{c} \mathrm{HBr}+\mathrm{O}_{2} \stackrel{k_{1}}{\longrightarrow} \mathrm{HOOBr} \\\ \mathrm{HOOBr}+\mathrm{HBr} \stackrel{k_{2}}{\longrightarrow} 2 \mathrm{HOBr} \\\ \mathrm{HOBr}+\mathrm{HBr} \stackrel{k_{3}}{\longrightarrow} \mathrm{H}_{2} \mathrm{O}+\mathrm{Br}_{2} \end{array}$$ You find that the rate is first order with respect to HBr and to \(\mathrm{O}_{2}\). You cannot detect HOBr among the products. (a) If the proposed mechanism is correct, which must be the rate-determining step? (b) Can you prove the mechanism from these observations? (c) Can you disprove the mechanism from these observations?

The following substrate concentration [S] versus time data were obtained during an enzyme-catalyzed reaction: \(t=0 \min ,[\mathrm{S}]=1.00 \mathrm{M} ; 20 \mathrm{min}, 0.90 \mathrm{M}; 60 \min , 0.70 \mathrm{M} ; 100 \mathrm{min}, 0.50 \mathrm{M} ; 160 \mathrm{min}, 0.20 \mathrm{M}.\) What is the order of this reaction with respect to \(\mathrm{S}\) in the concentration range studied?

Three different sets of data of \([\mathrm{A}]\) versus time are giv the following table for the reaction \(A \longrightarrow\) prod [Hint: There are several ways of arriving at answer each of the following six questions. $$\begin{array}{cccccc} \hline \text { I } & & \text { II } & & \text { III } & \\ \hline \begin{array}{c} \text { Time, } \\ \text { s } \end{array} & \text { [A], M } & \begin{array}{c} \text { Time, } \\ \text { s } \end{array} & \text { [A], M } & \begin{array}{c} \text { Time, } \\ \text { s } \end{array} & \text { [A], M } \\ \hline 0 & 1.00 & 0 & 1.00 & 0 & 1.00 \\ 25 & 0.78 & 25 & 0.75 & 25 & 0.80 \\ 50 & 0.61 & 50 & 0.50 & 50 & 0.67 \\ 75 & 0.47 & 75 & 0.25 & 75 & 0.57 \\ 100 & 0.37 & 100 & 0.00 & 100 & 0.50 \\ 150 & 0.22 & & & 150 & 0.40 \\ 200 & 0.14 & & & 200 & 0.33 \\ 250 & 0.08 & & & 250 & 0.29 \\ \hline \end{array}$$ Which of these sets of data corresponds to a (a) zero-order, (b) first-order, (c) second-order reaction?

One of the following statements is true and the other is false regarding the first-order reaction \(2 \overrightarrow{\mathrm{A}} \longrightarrow \mathrm{B}+\mathrm{C} .\) Identify the true statement and the false one, and explain your reasoning. (a) A graph of [A] versus time is a straight line. (b) The rate of the reaction is one-half the rate of disappearance of A.
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