Bundle: Chemistry: An Atoms First Approach, Loose-leaf Version, 2nd + OWLv2 with Student Solutions Manual, 4 terms (24 months) Printed Access Card
Bundle: Chemistry: An Atoms First Approach, Loose-leaf Version, 2nd + OWLv2 with Student Solutions Manual, 4 terms (24 months) Printed Access Card
2nd Edition
ISBN: 9781337086431
Author: Steven S. Zumdahl, Susan A. Zumdahl
Publisher: Cengage Learning
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Chapter 13, Problem 74E

(a)

Interpretation Introduction

Interpretation: The percent dissociation of the acid in each of the given solutions is to be calculated.

Concept introduction: At equilibrium, the equilibrium constant expression is expressed by the formula,

Ka=ConcentrationofproductsConcentrationofreactants

The percent dissociation of an acid is calculated by the formula,

Percentdissociation=Equilibriumconcentrationof[H+]Initialconcentrationoftheacid×100

To determine: The percent dissociation for a 0.20M solution of nitric acid (HNO3) .

(a)

Expert Solution
Check Mark

Answer to Problem 74E

Answer

The percent dissociation for the given 0.20M solution of nitric acid (HNO3) is 100%_ .

Explanation of Solution

Explanation

HNO3 is a strong acid. A strong acid completely dissociates in water.

Therefore, the [H+] is equal to the initial concentration of the acid.

Therefore, the [H+] is 0.20M_ .

The equilibrium concentration of [H+] is 0.20M .

The initial concentration of HNO3 is 0.20M .

The percent dissociation of an acid is calculated by the formula,

Percentdissociation=Equilibriumconcentrationof[H+]Initialconcentrationoftheacid×100

Substitute the value of the concentration of [H+] and the initial concentration of HNO3 in the above expression.

Percentdissociation=(0.200.20×100)%=100%_

(b)

Interpretation Introduction

Interpretation: The percent dissociation of the acid in each of the given solutions is to be calculated.

Concept introduction: At equilibrium, the equilibrium constant expression is expressed by the formula,

Ka=ConcentrationofproductsConcentrationofreactants

The percent dissociation of an acid is calculated by the formula,

Percentdissociation=Equilibriumconcentrationof[H+]Initialconcentrationoftheacid×100

To determine: The percent dissociation for a 0.20M solution of nitrous acid (HNO2) .

(b)

Expert Solution
Check Mark

Answer to Problem 74E

Answer

The percent dissociation for the given 0.20M solution of nitrous acid (HNO2) is 4.45%_ .

Explanation of Solution

Explanation

The equilibrium constant expression for the given reaction is, Ka=[H+][NO2][HNO2]

HNO2 is a comparatively stronger acid than H2O .

The dominant equilibrium reaction for the given case is,

HNO2(aq)H+(aq)+NO2(aq)

At equilibrium, the equilibrium constant expression is expressed by the formula,

Ka=ConcentrationofproductsConcentrationofreactants

Where,

  • Ka is the acid dissociation constant.

The equilibrium constant expression for the given reaction is,

Ka=[H+][NO2][HNO2] (1)

The [H+] is 8.9×10-3M_ .

The change in concentration of HNO2 is assumed to be x .

The ICE table for the stated reaction is,

HNO2(aq)H+(aq)+NO2(aq)Inititialconcentration0.2000Changex+x+xEquilibriumconcentration0.20xxx

The equilibrium concentration of [HNO2] is (0.20x)M .

The equilibrium concentration of [H+] is xM .

The equilibrium concentration of [NO2] is xM .

The Ka for HNO2 is 4.0×104 .

Substitute the value of Ka , [HNO2] , [H+] and [HNO2] in equation (1).

Ka=[H+][NO2][HNO2]4.0×104=[x][x][0.20x]4.0×104=[x]2[0.20x]

The value of x will be very small as compared to 0.20 . Hence, it is ignored from the term [0.20x] .

Simplify the above expression.

4.0×104=[x]2[0.20][x]2=(8.0×105)[x]=8.9×10-3M_

Therefore, the [H+] that is equal to x is 8.9×10-3M_ .

The calculated concentration of [H+] is 8.9×103M .

The initial concentration of HNO2 is 0.20M .

The percent dissociation of an acid is calculated by the formula,

Percentdissociation=Equilibriumconcentrationof[H+]Initialconcentrationoftheacid×100

Substitute the value of the concentration of [H+] and the initial concentration of HNO2 in the above expression.

Percentdissociation=(8.9×1030.20×100)%=4.45%_

(c)

Interpretation Introduction

Interpretation: The percent dissociation of the acid in each of the given solutions is to be calculated.

Concept introduction: At equilibrium, the equilibrium constant expression is expressed by the formula,

Ka=ConcentrationofproductsConcentrationofreactants

The percent dissociation of an acid is calculated by the formula,

Percentdissociation=Equilibriumconcentrationof[H+]Initialconcentrationoftheacid×100

To determine: The percent dissociation for a 0.20M solution of phenol (C6H5OH) .

(c)

Expert Solution
Check Mark

Answer to Problem 74E

Answer

The percent dissociation for the given 0.20M solution of phenol (C6H5OH) is 0.0028%_ .

Explanation of Solution

Explanation

The equilibrium constant expression for the given reaction is, Ka=[H+][C6H5O][C6H5OH]

C6H5OH is a comparatively stronger acid than H2O .

The dominant equilibrium reaction for the given case is,

C6H5OH(aq)H+(aq)+C6H5O(aq)

At equilibrium, the equilibrium constant expression is expressed by the formula,

Ka=ConcentrationofproductsConcentrationofreactants

Where,

  • Ka is the acid dissociation constant.

The equilibrium constant expression for the given reaction is,

Ka=[H+][C6H5O][C6H5OH] (1)

The [H+] is 5.66×10-6M_ .

The change in concentration of C6H5OH is assumed to be x .

The ICE table for the stated reaction is,

C6H5OH(aq)H+(aq)+C6H5O(aq)Inititialconcentration0.2000Changex+x+xEquilibriumconcentration0.20xxx

The equilibrium concentration of [C6H5OH] is (0.20x)M .

The equilibrium concentration of [H+] is xM .

The equilibrium concentration of [C6H5O] is xM .

The Ka for C6H5OH is 1.6×1010 .

Substitute the value of Ka , [C6H5OH] , [H+] and [C6H5O] in equation (1).

Ka=[H+][C6H5O][C6H5OH]1.6×1010=[x][x][0.20x]1.6×1010=[x]2[0.20x]

The value of x will be very small as compared to 0.20 . Hence, it is ignored from the term [0.20x] .

Simplify the above expression.

1.6×1010=[x]2[0.20][x]2=(3.2×1011)[x]=5.66×10-6M_

Therefore, the [H+] that is equal to x is 5.66×10-6M_ .

The calculated concentration of [H+] is 5.66×106M .

The initial concentration of C6H5OH is 0.20M .

The percent dissociation of an acid is calculated by the formula,

Percentdissociation=Equilibriumconcentrationof[H+]Initialconcentrationoftheacid×100

Substitute the value of the concentration of [H+] and the initial concentration of HNO2 in the above expression.

Percentdissociation=(5.66×1060.20×100)%=0.0028%_ (1)

(d)

Interpretation Introduction

Interpretation: The percent dissociation of the acid in each of the given solutions is to be calculated.

Concept introduction: At equilibrium, the equilibrium constant expression is expressed by the formula,

Ka=ConcentrationofproductsConcentrationofreactants

The percent dissociation of an acid is calculated by the formula,

Percentdissociation=Equilibriumconcentrationof[H+]Initialconcentrationoftheacid×100

To determine: The relation of percent dissociation of an acid and the Ka value for the acid.

(d)

Expert Solution
Check Mark

Answer to Problem 74E

Answer

Percent dissociation of an acid increases with an increase in the Ka value for the acid.

Explanation of Solution

Explanation

The percent dissociation of an acid is directly proportional to the Ka value for the acid.

The Ka value for HNO3 is 1 .

The percent dissociation of HNO3 in water is 100% .

The Ka value for HNO2 is 4.0×104 .

The percent dissociation of HNO2 in water is 4.45% .

The Ka value for C6H5OH is 1.6×1010 .

The percent dissociation of C6H5OH in water is 0.0028% .

Therefore, it can be stated that the percent dissociation of an acid increases with an increase in the Ka value for the acid.

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Chapter 13 Solutions

Bundle: Chemistry: An Atoms First Approach, Loose-leaf Version, 2nd + OWLv2 with Student Solutions Manual, 4 terms (24 months) Printed Access Card

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