Chemistry
Chemistry
12th Edition
ISBN: 9780078021510
Author: Raymond Chang Dr., Kenneth Goldsby Professor
Publisher: McGraw-Hill Education
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Chapter 4, Problem 4.160QP

(a)

Interpretation Introduction

Interpretation:

The required mass of KMnO4 to prepare a final solution should be calculated and reason for why not the very dilute solution are directly prepared should be explained.

Concept introduction:

Volumetric principle:

  • In the neutralization reaction, the volume and concentration of initial components are equal to the volume and concentration of the final components.
  • In the dilution of the chemical solutions are using volumetric principle.
  • In the dilution process, the relationship between initial and final concentrations and volumes of solutions are given in the volumetric equation and it is,

Mc×mLc=Md×mLdMc=InitialconcentrationmLc=InitialvolumeMd=dilutedconcentrationmLd=dilutedvolume

Molarity:

The concentration of the solutions is given by the term of molarity and it is given by ratio between numbers of moles of solute present in litter of solution.

Molarity=No.molevolume(L)

Mole:

The mole of the solute is calculated by taken mass of solute divided by molar mass of the solute.

Mole=Mass(g)Molarmass(g)

(a)

Expert Solution
Check Mark

Answer to Problem 4.160QP

The required mass of KMnO4 to prepare a final solution is 3.29×10-5gKMnO4

Explanation of Solution

To record the given data,

Taken mass KMnO4 of in first dilution = 0.8214 g

Final Volume of KMnO4 in first dilution = 500 mL

Taken Volume of KMnO4 in second dilution = 2.000 mL

Final Volume of KMnO4 in second dilution = 1000 mL

Taken Volume of KMnO4 in third dilution= 10 mL

Final Volume of KMnO4 in third dilution = 250 mL

The taken mass and volumes of KMnO4 solutions are recorded as shown above.

Calculate the molarity of KMnO4 first diluted solution.

Molar mass of KMnO4 is 158.04 g

=0.8214gKMnO4×1molKMnO4158.04KMnO4=0.0051974mole

The molarity of KMnO4 is,

=0.00519740.500L=0.010395M

  • The taken mass of KMnO4 is divided by molar mass of KMnO4 to give the mole of taken KMnO4.
  • The calculated mole is dividing by volume of solution to give molarity of first diluted KMnO4 solution.
  • The molarity of first diluted KMnO4 solution is 0.010395M.

Calculate the molarity second diluted KMnO4 solution.

M1V1=M2V21000mL=0.0103952.000mL=0.0103952.000mL1000mL=2.079×10-5M

  • The calculated concentration and volume of first diluted KMnO4 solution are plugged in the above equation to give the concentration of second diluted KMnO4 solution.
  • The concentration of second diluted KMnO4 solution 2.079×10-5M

Calculate the molarity second third KMnO4 solution

M1V1=M2V2250mL=0.0000207910.0mL=0.00002079×10.0mL250mL=8.32×10-7M

  • The calculated concentration and volume of second diluted KMnO4 solution are plugged in the above equation to give the concentration of third diluted KMnO4 solution.
  • The concentration of third diluted KMnO4 solution 8.32×10-7M

Calculate the mass of KMnO4 in third solution

The mole of KMnO4 in third solution,

=8.32×10-7M1000mLsoln×250mL=2.08×10-7mole

The mass of KMnO4 in third solution is,

=2.08×10-7mole×158.04KMnO41molKMnO4=3.29×10-5gKMnO4

  • The calculated concentration and volume of third diluted KMnO4 solution are plugged in the above equation to give the mole of third diluted KMnO4 solution.
  • The mole of third diluted KMnO4 solution 2.08×10-7mole
  • The calculated mole of third diluted KMnO4 solution is multiplied by molar mass of KMnO4 to give mass of present in third diluted KMnO4 solution.
  • The mass of present in third diluted KMnO4 solution is 3.29×10-5gKMnO4

(b)

Interpretation Introduction

Interpretation:

The required mass of KMnO4 to prepare a final solution should be calculated and reason for why not the very dilute solution are directly prepared should be explained.

Concept introduction:

Volumetric principle:

  • In the neutralization reaction, the volume and concentration of initial components are equal to the volume and concentration of the final components.
  • In the dilution of the chemical solutions are using volumetric principle.
  • In the dilution process, the relationship between initial and final concentrations and volumes of solutions are given in the volumetric equation and it is,

Mc×mLc=Md×mLdMc=InitialconcentrationmLc=InitialvolumeMd=dilutedconcentrationmLd=dilutedvolume

Molarity:

The concentration of the solutions is given by the term of molarity and it is given by ratio between numbers of moles of solute present in litter of solution.

Molarity=No.molevolume(L)

Mole:

The mole of the solute is calculated by taken mass of solute divided by molar mass of the solute.

Mole=Mass(g)Molarmass(g)

(b)

Expert Solution
Check Mark

Answer to Problem 4.160QP

The weight of solutes to prepare a very dilute solution is too small to directly weigh accurately.  So it results in more errors.  Therefore, the direct preparation of very dilute solution is not a good method.

Explanation of Solution

To record the given data,

Taken mass KMnO4 of in first dilution = 0.8214 g

Final Volume of KMnO4 in first dilution = 500 mL

Taken Volume of KMnO4 in second dilution = 2.000 mL

Final Volume of KMnO4 in second dilution = 1000 mL

Taken Volume of KMnO4 in third dilution= 10 mL

Final Volume of KMnO4 in third dilution = 250 mL

The taken mass and volumes of KMnO4 solutions are recorded as shown above.

Explain reason for why not the very dilute solution are directly prepared.

  • The weight of solutes to prepare a very dilute solution is too small to directly weigh accurately.  So, it results in more errors.  Therefore, the direct preparation of very dilute solution is not a good method.

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Chapter 4 Solutions

Chemistry

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Solutions: Crash Course Chemistry #27; Author: Crash Course;https://www.youtube.com/watch?v=9h2f1Bjr0p4;License: Standard YouTube License, CC-BY