Chemistry: Principles and Practice
Chemistry: Principles and Practice
3rd Edition
ISBN: 9780534420123
Author: Daniel L. Reger, Scott R. Goode, David W. Ball, Edward Mercer
Publisher: Cengage Learning
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Chapter 15, Problem 15.67QE

(a)

Interpretation Introduction

Interpretation:

The fraction of acid ionized in 0.33 MHNO2 solution has to be determined.

Concept Introduction:

A weak acid in water produces a hydrogen ion and conjugate base. When weak acid dissolves in water, some acid molecules transfer proton to water.

In solution of weak acid, the actual concentration of the acid molecules becomes less because partial dissociation of acid has occurred and lost protons to form hydrogen ions.

The reaction is as follows:

  HA(aq)+H2O(l)H3O+(aq)+A(aq)

The reaction is as follows:

  HA(aq)+H2O(l)H3O+(aq)+A(aq)

The expression for Ka is as follows:

  Ka=[H3O+][A][HA]

For value of Ka of different acids. (Refer to 15.6 in the book).

The fraction ionized is equal to ratio of concentration of ionized acid to analytical concentration multiplied by 100.

    Fraction ionized=([A]CHA)(100%)

(a)

Expert Solution
Check Mark

Answer to Problem 15.67QE

The fraction of acid ionizedin 0.33 MHNO2 solution is 4.03545 %.

Explanation of Solution

The chemical equation for ionization of HNO2 is as follows:

    HNO2+H2OH3O++NO2

The concentration of HNO2 is 0.33 M.

Also, HNO2 is ionized into H3O+ and NO2. Therefore concentration of H3O+ is equal to NO2.

Consider the concentration of H3O+ and NO2 be x.

The ICE table for the above reaction is as follows:

  EquationHNO2+H2OH3O++NO2Initial(M)0.33 000Change(M)x +x+xEquilibrium(M)0.33xxx

The expression for Ka for ionization of HNO2 is as follows:

  Ka=[H3O+][NO2][HNO2]        (1)

Substitute 0.33 M for [HNO2], x for [H3O+], x for [NO2] and 5.6×104 for Ka in equation (1), the equation needed to solve for the concentration of the hydrogen ion is as follows:

  5.6×104=(x)(x)0.33x

Rearrange above equation to obtain the required quadratic equation to compute the concentration of hydrogen ion as follows:

  x2+5.6×104x1.848×104=0

Solve for x, therefore the concentration of hydrogen ion is as calculated follows:

  x=0.013317

Or,

  x=0.013317

Neglect, the negative value of x as concentration cannot be negative.

Therefore concentration of H3O+ is equal to NO2 and is 0.013317.

The equation for fraction of acid ionized of 0.075 MHNO2 solution is a follows:

  Fraction ionized=([NO2]CHA)(100%)        (2)

Substitute 0.013317 for [NO2] and 0.075 M for CHA in equation (2).

  Fraction ionized=(0.0133170.33)(100%)=4.03545 %

Hence, the fraction of acid ionized in 0.33 MHNO2 solution is 4.03545 %.

(b)

Interpretation Introduction

Interpretation:

The fraction of acid ionized in 0.016 MC6H5OH solution has to be determined.

Concept Introduction:

Refer to part (a).

(b)

Expert Solution
Check Mark

Answer to Problem 15.67QE

The fraction of acid ionized in 0.016 MC6H5OH solution is 0.007906 %.

Explanation of Solution

The chemical equation for ionization of C6H5OH is as follows:

    C6H5OH+H2OH3O++C6H5O

The concentration of C6H5COOH is 0.016 M.

Also, C6H5OH is ionized into H3O+ and C6H5O. Therefore, concentration of H3O+ is equal to C6H5O.

Consider the concentration of H3O+ and C6H5O be x.

The ICE table for the above reaction is as follows:

  EquationC6H5OH+H2OH3O++C6H5OInitial(M)0.016000Change(M)x +x+xEquilibrium(M)0.016xxx

The expression for Ka for ionization of C6H5OH  is as follows:

  Ka=[H3O+][C6H5O][C6H5OH]        (3)

Substitute 0.016 M for [C6H5OH], x for [H3O+], x for [C6H5O] and 1.0×1010 for Ka in equation (3), the equation needed to solve for the concentration of the hydrogen ion is as follows:

  1.0×1010=(x)(x)0.016x

Rearrange above equation to obtain the required quadratic equation to compute the concentration of hydrogen ion as follows:

  x2+1.0×1010x0.016×1010=0

Solve for x, therefore the concentration of hydrogen ion is as calculated follows:

  x=1.26496×106

Or,

  x=1.26496×106

Neglect, the negative value of x as concentration cannot be negative.

Therefore, concentration of H3O+ is equal to C6H5O and is 1.26496×106.

The equation for fraction of acid ionized in 0.016 MC6H5OH solution is a follows:

  Fraction ionized=([C6H5O]CHA)(100%)        (4)

Substitute 1.26496×106 for [C6H5O] and 0.016 M for CHA in equation (4), fraction ionized is calculated as follows:

  Fraction ionized=(1.26496×1060.016)(100%)=0.007906 %

Hence, the fraction of acid ionized in 0.016 MC6H5OH solution is 0.007906 %.

(c)

Interpretation Introduction

Interpretation:

The fraction of acid ionized in 0.25 MHF solution has to be determined.

Concept Introduction:

Refer to part (a).

(c)

Expert Solution
Check Mark

Answer to Problem 15.67QE

The fraction of acid ionized in 0.25 MHF solution is 4.94548 %.

Explanation of Solution

The chemical equation for ionization of HF is as follows:

    HF+H2OH3O++F

The concentration of HF is 0.25 M.

Also, HF is ionized into H3O+ and F. Therefore concentration of H3O+ is equal to F.

Let us assume the concentration of H3O+ and F be x.

The ICE table for the above reaction is as follows:

  EquationHF+H2OH3O++FInitial(M)0.25000Change(M)x +x+xEquilibrium(M)0.25xxx

The expression for Ka for ionization of HF is as follows:

  Ka=[H3O+][F][HF]        (5)

Substitute 0.25 M for HF, x for [H3O+], x for [F] and 6.3×104 for Ka in equation (5), the equation needed to solve for the concentration of the hydrogen ion is as follows:

  6.3×104=(x)(x)0.255x

Rearrange above equation to obtain the required quadratic equation to compute the concentration of hydrogen ion as follows:

  x2+6.3×104x1.6065×104=0

Solve for x, therefore the concentration of hydrogen ion is as calculated follows:

  x=0.0123637

Or,

  x=0.0123637

Neglect, the negative value of x as concentration cannot be negative.

Therefore, concentration of H3O+ and F is 0.0123637.

The equation for fraction of acid ionized in 0.25 MHF solution is a follows:

  Fraction ionized=([F]CHA)(100%)        (6)

Substitute 0.0123637 for [F] and 0.25 M for CHA in equation (

  Fraction ionized=(0.01236370.25)(100%)=4.94548 %

Hence, the fraction of acid ionized in 0.25 MHF solution is 4.94548 %.

(d)

Interpretation Introduction

Interpretation:

The fraction of acid ionized in 0.010 MHCOOH solution has to be determined.

Concept Introduction:

Refer to part (a).

(d)

Expert Solution
Check Mark

Answer to Problem 15.67QE

The fraction of acid ionized in 0.010 MHCOOH solution 12.3637 %

Explanation of Solution

The chemical equation for ionization of HCOOH is as follows:

    HCOOH+H2OH3O++HCOO

The concentration of HCOOH is 0.010 M.

Also, HCOOH is ionized into H3O+ and HCOO. Therefore, concentration of H3O+ is equal to HCOO.

Let us assume the concentration of H3O+ and HCOO be x.

The ICE table for the above reaction is as follows:

  EquationHCOOH+H2OH3O++HCOOInitial(M)0.010000Change(M)x +x+xEquilibrium(M)0.010xxx

The expression for Ka for ionization of HCOOH  is as follows:

  Ka=[H3O+][HCOO][HCOOH]        (7)

Substitute 0.010 M for HCOOH, x for [H3O+], x for [HCOO] and 1.8×104 for Ka in equation (7), the equation needed to solve for the concentration of the hydrogen ion is as follows:

  1.8×104=(x)(x)0.010x

Rearrange above equation to obtain the required quadratic equation to compute the concentration of hydrogen ion as follows:

  x2+1.8×104x0.018×104=0

Solve for x, therefore the concentration of hydrogen ion is as calculated follows:

  x=0.00125466

Or,

  x=0.00125466

Neglect, the negative value of x as concentration cannot be negative.

Therefore, concentration of H3O+ is 0.00125466.

The equation for fraction of acid ionized in 0.010 MHCOOH solution is a follows:

  Fraction ionized=([HCOO]CHA)(100%)        (8)

Substitute 0.00125466 for [HCOO] and 0.010 M for CHA in equation (8).

  Fraction ionized=(0.001254660.010)(100%)=12.3637 %

Hence, the fraction of acid ionized in 0.010 MHCOOH solution is 12.3637 %.

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Chapter 15 Solutions

Chemistry: Principles and Practice

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