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Chapter 14: Problem 103

The \(\mathrm{pH}\) of a \(0.016-M\) aqueous solution of \(p\) -toluidine \(\left(\mathrm{CH}_{3} \mathrm{C}_{6} \mathrm{H}_{4} \mathrm{NH}_{2}\right)\) is 8.60 . Calculate \(K_{\mathrm{b}}\) .

Short Answer

Expert verified
The base dissociation constant, \(K_b\), for p-toluidine is approximately \(9.96 \times 10^{-10}\).

Step by step solution

01

Convert pH to pOH

Recall the relationship between pH, pOH, and the ion product constant for water, Kw: \(pH + pOH = 14\) Given the pH of the p-toluidine solution, we can find the pOH as follows: \(pOH = 14 - pH = 14 - 8.60 = 5.40\)
02

Calculate the concentration of OH- ions

Now that we have the pOH, we can calculate the concentration of OH- ions using the following formula: \[OH^{-} = 10^{-pOH}\] Plugging in the found pOH value: \[OH^{-} = 10^{-5.40} = 3.98 \times 10^{-6}\,M\]
03

Set up the Kb expression

The Kb expression for p-toluidine \((CH_{3}C_{6}H_{4}NH_{2})\) is as follows: \[K_{b} = \frac{[OH^{-}][CH_{3}C_{6}H_{4}NH_{3}^{+}]}{[CH_{3}C_{6}H_{4}NH_{2}]}\] At equilibrium, the concentration of p-toluidine, [\(CH_{3}C_{6}H_{4}NH_{2}\)], is equal to its initial concentration minus the concentration of OH- ions produced. Since p-toluidine is a weak base and does not dissociate completely, we can assume that the change in its concentration will be small, so it can be approximated as follows: \[[CH_{3}C_{6}H_{4}NH_{2}] \approx 0.016\,M - [OH^{-}]\] The concentration of p-toluidine cation, [\(CH_{3}C_{6}H_{4}NH_{3}^{+}\)], is equal to the concentration of OH- ions produced: \[[CH_{3}C_{6}H_{4}NH_{3}^{+}] = [OH^{-}]\] Now we can substitute these expressions into the Kb expression: \[K_{b} = \frac{[OH^{-}][OH^{-}]}{(0.016\,M - [OH^{-}])}\]
04

Solve for Kb

We can now solve for Kb using the concentration of OH- ions calculated in Step 2: \[K_{b} = \frac{(3.98 \times 10^{-6})^2}{(0.016 - 3.98 \times 10^{-6})}\] Simplifying the expression and solving for Kb: \[K_{b} \approx 9.96 \times 10^{-10}\] So, the base dissociation constant, Kb, for p-toluidine is approximately \(9.96 \times 10^{-10}\).

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Key Concepts

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

p-toluidine
P-toluidine, chemically known as methyl aniline, is a type of organic compound. It falls under the category of amines, which are derivatives of ammonia. It comprises a toluene group attached to an amine group. The chemical formula for p-toluidine is \( \mathrm{CH}_3\mathrm{C}_6\mathrm{H}_4\mathrm{NH}_2 \).
This compound is often used in the production of dyes, pharmaceuticals, and other chemicals.

**Properties of p-toluidine:**
  • It is a weak base, meaning it does not completely ionize in aqueous solutions.
  • In solution, p-toluidine has the potential to accept protons and form a conjugate acid.
  • Given its weak base nature, p-toluidine has a specific base dissociation constant, \( K_b \), which quantifies its ability to ionize in water.
Understanding these properties is important in calculating the equilibrium concentrations in solutions involving p-toluidine.
pH calculation
pH is a measure of the acidity or basicity of an aqueous solution. In this specific problem, we're interested in the pH of a p-toluidine solution. The pH scale ranges from 0 to 14, where 7 is neutral, lower values are acidic, and higher values are basic.
For p-toluidine, with a solution having a pH of 8.60, it indicates a basic nature due to the presence of the weak base in the solution.

**Steps in pH Calculation:**
  • Obtain the pH value from experiment or calculation.
  • Utilize this pH value in other computations, as pH is intrinsically related to the concentration of hydrogen ions in the solution: \( \text{pH} = -\log[H^+] \).
This concept will be used along with pOH to determine other characteristics of the solution, demonstrating the interrelationship between various aspects of chemistry.
pOH
pOH is a counterpart to pH, and together they provide a full picture of ionic activity in an aqueous solution. The pOH value signifies the concentration of hydroxide ions, \( \text{OH}^- \), in the solution. Like pH, pOH follows a logarithmic scale.
The relationship between pH and pOH is governed by the equation:\[ \text{pH} + \text{pOH} = 14 \]

**How to Calculate pOH:**
  • Given the pH of the solution, calculate pOH using the equation: \( \text{pOH} = 14 - \text{pH} \).
  • Using the calculated pOH, find the concentration of hydroxide ions: \( [\text{OH}^-] = 10^{-\text{pOH}} \).
This step is crucial because it helps to determine the degree of ionization of the base, thereby enabling us to find the equilibrium concentrations needed to solve for the base dissociation constant \( K_b \).
equilibrium concentrations
Understanding equilibrium concentrations allows us to predict how a chemical system at equilibrium reacts to external changes. For weak bases like p-toluidine, it’s essential to calculate these concentrations as they affect the base dissociation constant \( K_b \).

**Calculating Equilibrium Concentrations: **
  • Start with the initial concentration of the weak base (in this case, \( 0.016 \) M for p-toluidine).
  • Determine the change in concentration as the base undergoes partial ionization to produce hydroxide ions \( [\text{OH}^-] \).
  • At equilibrium, calculate the concentration of the conjugate acid formed, which equals \([\text{OH}^-] \) due to the stoichiometry.
  • Use these concentrations to write and solve the expression for \( K_b \):
    \[ K_b = \frac{[\text{OH}^-][\text{conjugate acid}]}{[\text{base]} \text{ at equilibrium}} \]
By solving this expression, you can deduce the value of \( K_b \), giving insight into the weak base’s ability to dissociate in water.

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Most popular questions from this chapter

Calculate the percent dissociation for a \(0.22-M\) solution of chlorous acid \(\left(\mathrm{HClO}_{2}, K_{\mathrm{a}}=0.012\right)\)

Quinine \(\left(\mathrm{C}_{20} \mathrm{H}_{24} \mathrm{N}_{2} \mathrm{O}_{2}\right)\) is the most important alkaloid derived from cinchona bark. It is used as an antimalarial drug. For quinine, \(\mathrm{p} K_{\mathrm{b}_{1}}=5.1\) and \(\mathrm{p} K_{\mathrm{b}_{2}}=9.7\left(\mathrm{p} K_{\mathrm{b}}=-\log K_{\mathrm{b}}\right) .\) Only 1 g quinine will dissolve in 1900.0 \(\mathrm{mL}\) of solution. Calculate the pH of a saturated aqueous solution of quinine. Consider only the reaction \(\mathrm{Q}+\mathrm{H}_{2} \mathrm{O} \rightleftharpoons \mathrm{QH}^{+}+\mathrm{OH}^{-}\) described by \(\mathrm{p} K_{\mathrm{b}_{1}},\) where \(\mathrm{Q}=\) quinine.

Write the reaction and the corresponding \(K_{\mathrm{b}}\) equilibrium expression for each of the following substances acting as bases in water. a. \(\mathrm{NH}_{3}\) b. \(\mathrm{C}_{5} \mathrm{H}_{5} \mathrm{N}\)

What mass of \(\mathrm{NaOH}(s)\) must be added to 1.0 \(\mathrm{L}\) of 0.050 \(\mathrm{M}\) \(\mathrm{NH}_{3}\) to ensure that the percent ionization of \(\mathrm{NH}_{3}\) is no greater than 0.0010\(\% ?\) Assume no volume change on addition of \(\mathrm{NaOH} .\)

Are solutions of the following salts acidic, basic, or neutral? For those that are not neutral, write balanced equations for the reactions causing the solution to be acidic or basic. The relevant \(K_{\mathrm{a}}\) and \(K_{\mathrm{b}}\) values are found in Tables 14.2 and \(14.3 .\) \(\begin{array}{ll}{\text { a. } \operatorname{Sr}\left(\mathrm{NO}_{3}\right)_{2}} & {\text { d. } \mathrm{C}_{6} \mathrm{H}_{5} \mathrm{NH}_{3} \mathrm{ClO}_{2}} \\ {\text { b. } \mathrm{NH}_{4} \mathrm{C}_{2} \mathrm{H}_{3} \mathrm{O}_{2}} & {\text { e. } \mathrm{NH}_{4} \mathrm{F}} \\ {\text { c. } \mathrm{CH}_{3} \mathrm{NH}_{3} \mathrm{O} \mathrm{l}} & {\text { f. } \mathrm{CH}_{3} \mathrm{NH}_{3} \mathrm{CN}}\end{array}\)
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