Bundle: Introductory Chemistry: A Foundation, 8th + OWLv2 6-Months Printed Access Card
Bundle: Introductory Chemistry: A Foundation, 8th + OWLv2 6-Months Printed Access Card
8th Edition
ISBN: 9781305367333
Author: Steven S. Zumdahl, Donald J. DeCoste
Publisher: Cengage Learning
Question
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Chapter 15, Problem 56QAP
Interpretation Introduction

(a)

Interpretation:

The new molarity after the addition of water is to be calculated.

Concept Introduction:

The atomic mass of an element is defined as the sum of number of protons and number of neutrons. Molar mass of an element is determined from atomic mass of an element.

The number of moles is calculated by the formula,

Moles=MassgMolarmass

The molarity is calculated by the formula,

Molarity=NumberofmolesofsoluteVolumeofsolution.

Expert Solution
Check Mark

Answer to Problem 56QAP

The new molarity that results when 250.0mL of water is added to the given solution is 0.0837M.

Explanation of Solution

The initial volume and molarity of HCl solution is given to be 125mL and 0.251M respectively.

The conversion of units of 125mL into L is done as,

125mL=12501000L=0.125L

The number of moles of a solute is calculated by the formula,

Numberofmolesofsolute=Volumeofsolution×Molarity        (1)

Substitute the values of initial volume and molarity of HCl solution in the equation (1).

Numberofmolesofsolute=0.125L×0.251M=0.0314moles

It is given that 250.0mL of water is added in the given solution. During the dilution, the amount of the solute particles in initial and final solution remains same, only the amount of solvent gets changed.

The conversion of units of 250.0mL into L is done as,

250.0mL=250.01000L=0.250L

Thus, the total volume is calculated by the formula,

Finalvolume=Initialvolume+Volumeofwateradded        (2)

Substitute the values of initial volume and volume of water added in the equation (2).

Finalvolume=0.125L+0.250L=0.375L

The new molarity of the solution is calculated by the formula,

Molarity=NumberofmolesofsoluteVolumeofsolutionL        (3)

Substitute the values of number of moles of solute and final volume in the equation (3).

Molarity=0.0314moles0.375L=0.0837M

Therefore, the new molarity that results when 250.0mL of water is added to the given solution is 0.0837M.

Interpretation Introduction

(b)

Interpretation:

The new molarity after the addition of water is to be calculated.

Concept Introduction:

The atomic mass of an element is defined as the sum of number of protons and number of neutrons. Molar mass of an element is determined from atomic mass of an element.

The number of moles is calculated by the formula,

Moles=MassgMolarmass

The molarity is calculated by the formula,

Molarity=NumberofmolesofsoluteVolumeofsolution.

Expert Solution
Check Mark

Answer to Problem 56QAP

The new molarity that results when 250.0mL of water is added to the given solution is 0.319M.

Explanation of Solution

The initial volume and molarity of H2SO4 solution is given to be 445mL and 0.499M respectively.

The conversion of units of 445mL into L is done as,

445mL=4451000L=0.445L

The number of moles of a solute is calculated by the formula,

Numberofmolesofsolute=Volumeofsolution×Molarity        (1)

Substitute the values of initial volume and molarity of H2SO4 solution in the equation (1).

Numberofmolesofsolute=0.445L×0.499M=0.222moles

It is given that 250.0mL of water is added in the given solution. During the dilution, the amount of the solute particles in initial and final solution remains same, only the amount of solvent get changes.

The conversion of units of 250.0mL into L is done as,

250.0mL=250.01000L=0.250L

Thus, the total volume is calculated by the formula,

Finalvolume=Initialvolume+Volumeofwateradded        (2)

Substitute the values of initial volume and volume of water added in the equation (2).

Finalvolume=0.445L+0.250L=0.695L

The new molarity of the solution is calculated by the formula,

Molarity=NumberofmolesofsoluteVolumeofsolutionL        (3)

Substitute the values of number of moles of solute and final volume in the equation (3).

Molarity=0.222moles0.695L=0.319M

Therefore, the new molarity that results when 250.0mL of water is added to the given solution is 0.319M.

Interpretation Introduction

(c)

Interpretation:

The new molarity after the addition of water is to be calculated.

Concept Introduction:

The atomic mass of an element is defined as the sum of number of protons and number of neutrons. Molar mass of an element is determined from atomic mass of an element.

The number of moles is calculated by the formula,

Moles=MassgMolarmass

The molarity is calculated by the formula,

Molarity=NumberofmolesofsoluteVolumeofsolution.

Expert Solution
Check Mark

Answer to Problem 56QAP

The new molarity that results when 250.0mL of water is added to the given solution is 0.0964M.

Explanation of Solution

The initial volume and molarity of HNO3 solution is given to be 5.25L and 0.101M respectively.

The number of moles of a solute is calculated by the formula,

Numberofmolesofsolute=Volumeofsolution×Molarity        (1)

Substitute the values of initial volume and molarity of HNO3 solution in the equation (1).

Numberofmolesofsolute=5.25L×0.101M=0.530moles

It is given that 250.0mL of water is added in the given solution. During the dilution, the amount of the solute particles in initial and final solution remains same, only the amount of solvent gets changed.

The conversion of units of 250.0mL into L is done as,

250.0mL=250.01000L=0.250L

Thus, the total volume is calculated by the formula,

Finalvolume=Initialvolume+Volumeofwateradded        (2)

Substitute the values of initial volume and volume of water added in the equation (2).

Finalvolume=5.25L+0.250L=5.5L

The new molarity of the solution is calculated by the formula,

Molarity=NumberofmolesofsoluteVolumeofsolutionL        (3)

Substitute the values of number of moles of solute and final volume in the equation (3).

Molarity=0.530moles5.5L=0.0964M

Therefore, the new molarity that results when 250.0mL of water is added to the given solution is 0.0964M.

Interpretation Introduction

(d)

Interpretation:

The new molarity after the addition of water is to be calculated.

Concept Introduction:

The atomic mass of an element is defined as the sum of number of protons and number of neutrons. Molar mass of an element is determined from atomic mass of an element.

The number of moles is calculated by the formula,

Moles=MassgMolarmass

The molarity is calculated by the formula,

Molarity=NumberofmolesofsoluteVolumeofsolution.

Expert Solution
Check Mark

Answer to Problem 56QAP

The new molarity that results when 250.0mL of water is added to the given solution is 0.6217M.

Explanation of Solution

The initial volume and molarity of HC2H3O2 solution is given to be 11.2mL and 14.5M respectively.

The conversion of units of 11.2mL into L is done as,

11.2mL=11.21000L=0.0112L

The number of moles of a solute is calculated by the formula,

Numberofmolesofsolute=Volumeofsolution×Molarity        (1)

Substitute the values of initial volume and molarity of HC2H3O2 solution in the equation (1).

Numberofmolesofsolute=0.0112L×14.5M=0.1624moles

It is given that 250.0mL of water is added in the given solution. During the dilution, the amount of the solute particles in initial and final solution remains same, only the amount of solvent get changes.

The conversion of units of 250.0mL into L is done as,

250.0mL=250.01000L=0.250L

Thus, the total volume is calculated by the formula,

Finalvolume=Initialvolume+Volumeofwateradded        (2)

Substitute the values of initial volume and volume of water added in the equation (2).

Finalvolume=0.0112L+0.250L=0.2612L

The new molarity of the solution is calculated by the formula,

Molarity=NumberofmolesofsoluteVolumeofsolutionL        (3)

Substitute the values of number of moles of solute and final volume in the equation (3).

Molarity=0.1624moles0.2612L=0.6217M

Therefore, the new molarity that results when 250.0mL of water is added to the given solution is 0.6217M.

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Chapter 15 Solutions

Bundle: Introductory Chemistry: A Foundation, 8th + OWLv2 6-Months Printed Access Card

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Can you give an...Ch. 15 - ow do the properties of a nonhomogeneous...Ch. 15 - Prob. 3QAPCh. 15 - Prob. 4QAPCh. 15 - n Chapter 14. you learned that the bonding forces...Ch. 15 - n oil spill spreads out on the surface of water,...Ch. 15 - . 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Suppose 325 in L of 0.150 M NaOH is needed for...Ch. 15 - 61. How much water must be added w 500. mL of...Ch. 15 - An experiment calls for 100. mL of 1.25 M HC1. All...Ch. 15 - Prob. 63QAPCh. 15 - 64. Generally only the carbonates of the Group I...Ch. 15 - 65. Many metal ions are precipitated from solution...Ch. 15 - 66. Calcium oxalate, CaCO4, is very insoluble in...Ch. 15 - 67. When aqueous solutions of lead(II) ion are...Ch. 15 - 68. Aluminum ion may be precipitated from aqueous...Ch. 15 - 69. What volume of 0.502 M NaOH solution would be...Ch. 15 - 70. What volume of a 0.500 M NaOH solution would...Ch. 15 - 71. A sample of sodium hydrogen carbonate solid...Ch. 15 - 72. The total acidity in water samples can be...Ch. 15 - Prob. 73QAPCh. 15 - Prob. 74QAPCh. 15 - Prob. 75QAPCh. 15 - Prob. 76QAPCh. 15 - 77. 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