Introductory Chemistry: A Foundation
Introductory Chemistry: A Foundation
8th Edition
ISBN: 9781285199030
Author: Steven S. Zumdahl, Donald J. DeCoste
Publisher: Cengage Learning
Question
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Chapter 15, Problem 27CR
Interpretation Introduction

Interpretation:

One equivalent of an acid is to be defined. An equivalent of a base is to be explained. The relation between the equivalent weight of an acid or a base and the substance’s molar mass is to be explained. An example of an acid and a base that have equivalent weights equal to their molar masses is to be stated. An example of an acid and a base that have equivalent weights that are not equal to their molar masses is to be given. The normal solution of an acid or a base is to be defined. The relation between the normality of an acid or a base solution and its molarity is to be explained. An example of a solution that has equal normality and molarity, and an example of a solution that have different normality and molarity is to be stated.

Concept Introduction:

The molarity of a solution is the molar concentration of the solution; it measures the number of moles of solute dissolved in one liter of the solution. The formula for molarity is given as,

M=nV

Where,

  • n represents the number of moles of the solute.
  • V represents the volume of the solution.

The normality of a solution is referred as the gram equivalent weight of a solute dissolved in one liter of the solution. The normality of solution is given as:

N=neqV

Where,

  • neq represents the number of equivalents of the solute.
  • V represents the volume of the solution.

Expert Solution & Answer
Check Mark

Answer to Problem 27CR

One equivalent of an acid is defined as amount of the acid solution that has one mole of H+ ion. An equivalent of a base represents a base solution that has one mole of OH ions.

The relation between the equivalent weight of an acid or a base and the substance’s molar mass is represented as,

Meq=Mmn

An acid that has equivalent weights equal to its molar masses is HCl and a base that has equivalent weights equal to its molar masses is NaOH. An acid that has equivalent weights that are not equal to its molar masses is H2SO4 and a base that has equivalent weights that are not equal to its molar masses is CaOH2. A normal solution of an acid or a base is defined as the solution in which one mole of H+ or OH ions are dissolved in one liter of the solution.

The relation between the normality of an acid or a base solution and its molarity is given as,

N=n'M

An example of a solution that has equal normality and molarity is HCl, and an example of a solution that has different normality and molarity is H2SO4.

Explanation of Solution

One equivalent of an acid is defined as amount of the acid solution that has one mole of H+ ion. An equivalent of a base represents a base solution that has one mole of OH ions.

The relation between the equivalent weight of an acid or a base and the substance’s molar mass is represented as,

Meq=Mmn    (1)

Where,

  • Mm represents the molar mass of the substance.
  • n represents the equivalence factor of the substance.
  • Meq represents the equivalent weight of the substance.

The dissociation reaction of HCl in water is represented as:

HClaqH+aq+Claq

The number of H+ ion released by HCl is 1.

Hence the equivalence factor of HCl is 1eqmol1.

The molar mass of HCl is 36.469gmol1.

Substitute the value of Mm and n in the equation (1).

Meq=36.469gmol11eqmol1=36.469geq1

Therefore, HCl has equal molar mass and equivalent weight.

The dissociation reaction of NaOH in water is represented as,

NaOHaqNa+aq+OHaq

The number of OH ion released by NaOH is 1.

Hence the equivalence factor of NaOH is 1eqmol1.

The molar mass of NaOH is 39.9979gmol1.

Substitute the value of Mm and n in the equation (1).

Meq=39.9979gmol11eqmol1=39.9979geq1

Therefore, NaOH has equal molar mass and equivalent weight.

The dissociation reaction of H2SO4 in water is represented as,

H2SO4aq2H+aq+SO42aq

The number of H+ ion released by H2SO4 is 2.

Hence the equivalence factor of H2SO4 is 2eqmol1.

The molar mass of H2SO4 is 98.079gmol1.

Substitute the value of Mm and n in the equation (1).

Meq=98.079gmol12eqmol1=49.0395geq1

Therefore, H2SO4 has different molar mass and equivalent weight.

The dissociation reaction of CaOH2 in water is represented as,

CaOH2aq2OHaq+Ca2+aq

The number of OH ion released by CaOH2 is 2.

Hence the equivalence factor of CaOH2 is 2eqmol1.

The molar mass of CaOH2 is 74.093gmol1.

Substitute the value of Mm and n in the equation (1).

Meq=74.093gmol12eqmol1=37.0465geq1

Therefore, CaOH2 has different molar mass and equivalent weight.

The relationship between the molarity and normality of a solution is given as,

N=n'M

Where,

  • N represents the normality of the solution.
  • M represents the molarity of the solution.
  • n' represents the equivalence factor of the solute.

The equivalence factor of HCl is one therefore, HCl has equal normality and molarity.

The equivalence factor of H2SO4 is not equal to one therefore, H2SO4 has different normality and molarity.

Conclusion

One equivalent of an acid is defined as the quantity of the acid solution that has one mole of H+ ion. An equivalent of a base represents a base solution that has one mole of OH ions.

The relation between the equivalent weight of an acid or a base and the substance’s molar mass is represented as,

Meq=Mmn

Where,

  • Mm represents the molar mass of the substance.
  • n represents the equivalence factor of the substance.
  • Meq represents the equivalent weight of the substance.

An example of an acid that has equivalent weights equal to its molar masses is HCl and an example of a base that has equivalent weights equal to its molar masses is NaOH. An example of an acid that has equivalent weights that are not equal to its molar masses is H2SO4 and an example of a base that has equivalent weights that are not equal to its molar masses is CaOH2. A normal solution of an acid or a base is defined as the solution in which one mole of H+ or OH ions are dissolved in one liter of the solution.

The relation between the normality of an acid or a base solution and its molarity is given as,

N=n'M

Where,

  • N represents the normality of the solution.
  • M represents the molarity of the solution.
  • n' represents the equivalence factor of the solute.

The HCl solution has equal normality and molarity, and the H2SO4 solution has different normality and molarity.

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Chapter 15 Solutions

Introductory Chemistry: A Foundation

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