Introductory Chemistry: A Foundation
Introductory Chemistry: A Foundation
9th Edition
ISBN: 9781337399425
Author: Steven S. Zumdahl, Donald J. DeCoste
Publisher: Cengage Learning
Question
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Chapter 15, Problem 38CR
Interpretation Introduction

(a)

Interpretation:

The mass of pure H2SO4 present in pure 125mL sample is to be calculated.

Concept Introduction:

The mass percentage of a compound present in a solution is calculated by dividing the mass of the compound present in the solution by the total mass of the solution and then multiplying it by 100. The formula for mass percentage is represented as,

mass%=MMt×100%

Where,

  • M represents the mass of the compound present in the solution.
  • Mt represents the total mass of solution.

Expert Solution
Check Mark

Answer to Problem 38CR

The mass of pure H2SO4 present in 125mL sample of concentrated sulfuric acid solution is 226.09g.

Explanation of Solution

The volume of the concentrated sulfuric acid solution is 125mL.

The density of the concentrated sulfuric acid solution is 1.84g/mL.

The mass percentage of H2SO4 in the given solution is 98.3%.

The relation between mass, volume and density of a substance is given as,

m=VD

Where,

  • V represents the volume occupied by the substance.
  • m represents the mass of the substance.
  • D represents the density of the substance.

Substitute the value of density and volume of sulfuric acid solution in the above equation.

m=125mL1.84g/mL=230.00g

The formula for mass percentage is represented as,

mass%=MMt×100%

Where,

  • M represents the mass of the compound present in the solution.
  • Mt represents the total mass of solution.

Rearrange the above equation for the value of M.

M=Mt×mass%100%

Substitute the value of mass of concentrated sulfuric acid solution and mass percentage of sulfuric acid in the above equation.

M=230.00g98.3%100%=226.09g

Therefore, the mass of pure H2SO4 present in 125mL sample of concentrated sulfuric acid solution is 226.09g.

Interpretation Introduction

(b)

Interpretation:

The molarity of given concentrated acid solution is to be calculated.

Concept Introduction:

The molarity of a solution is defined as the number of mole 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.

Expert Solution
Check Mark

Answer to Problem 38CR

The molarity of the given H2SO4 solution is 18.44M.

Explanation of Solution

The mass of H2SO4 taken is 226.09g.

The volume of the H2SO4 solution is 125mL.

The molar mass of H2SO4 is 98.079gmol1.

The molarity of a solution is given as,

M=mMmV

Where,

  • m represents the mass of the solute.
  • V represents the volume of the solution.
  • Mm represents the molar mass of the solute.

Substitute the value of m, V and Mm in the above equation.

M=226.09g1M1molL198.07gmol1125mL1L1000mL=18.44M

Therefore, the molarity of the given H2SO4 solution is 18.44M.

Interpretation Introduction

(c)

Interpretation:

The molarity of the given acid solution after dilution is to be calculated.

Concept Introduction:

The molarity of a solution is defined as 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.

Expert Solution
Check Mark

Answer to Problem 38CR

The molarity of the given acid solution after dilution is 0.766M.

Explanation of Solution

The initial molarity of the H2SO4 solution is 18.44M.

The initial volume of the H2SO4 solution is 125mL.

The final volume of H2SO4 solution is 3.01L.

The relation between the initial and final volume of a solution is given as,

MfVf=MiVi

Where,

  • Mf represents the final molarity of the solution.
  • Vf represents the final volume of the solution.
  • Mi represents the initial molarity of the solution.
  • Vi represents the initial volume of the solution.

Rearrange the above equation for the value of Mf.

Mf=MiViVf

Substitute the value of Vf, Mi and Vi in the above equation.

Mf=18.44M125mL3.01L1000mL1L=0.766M

Therefore, the molarity of the given acid solution after dilution is 0.766M.

Interpretation Introduction

(d)

Interpretation:

The normality of the dilute acid solution is to be calculated.

Concept Introduction:

The normality of a solution is defined 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
Check Mark

Answer to Problem 38CR

The normality of the diluted H2SO4 solution is 1.532N.

Explanation of Solution

The molarity of the diluted solution of H2SO4 is 0.766M.

The volume of 0.766MH2SO4 solution is 3.01L.

The dissociation of sulfuric acid in water is represented as:

H2SO4aq2H+aq+SO42aq

Therefore, the equivalence factor of H2SO4 is 2eqmol1.

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.

Substitute the value of M and n' in the above equation.

N=2eqmol10.766M1molL11M1N1eqL1=1.532N

Therefore, the normality of the diluted H2SO4 solution is 1.532N.

Interpretation Introduction

(e)

Interpretation:

The volume of dilute acid solution required to neutralize 45.3mL of 0.532MNaOH solution is to be calculated.

Concept Introduction:

Neutralization is the process in which an acid and base react with each other to give salt and water. The general reaction of acid and base is represented as,

AH+BOHAB+H2O

The molarity of a solution is defined as 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.

Expert Solution
Check Mark

Answer to Problem 38CR

The volume of dilute acid solution required to neutralize 36.2mL of 0.532MNaOH is 15.7308mL.

Explanation of Solution

The molarity of the dilute H2SO4 solution is 0.766M.

The molarity of the given NaOH solution is 0.532M.

The volume of the 0.532MNaOH is 45.3mL.

The neutralization reaction between H2SO4 and NaOH is represented as,

H2SO4aq+2NaOHaqNa2SO4aq+2H2Ol

The relation between molarities of H2SO4 and NaOH is given as,

2M1V1=M2V2

Where,

  • M1 represents the molarity of H2SO4.
  • V1 represents the volume of H2SO4.
  • M2 represents the molarity of NaOH.
  • V2 represents the volume of NaOH.

Rearrange the above equation for the value of V1.

V1=M2V22M1

Substitute the value M1, M2 and V2 in the above equation.

V1=0.532M45.3mL20.766M=15.7308mL

Therefore, the volume of dilute acid solution required to neutralize 36.2mL of 0.532MNaOH is 15.7308mL.

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Chapter 15 Solutions

Introductory Chemistry: A Foundation

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