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 120AP
Interpretation Introduction

(a)

Interpretation:

The number of moles of each ion present in 1.25L of 0.250MNa3PO4 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 120AP

The number of moles of Na+ and PO43 ions present in 1.25L of 0.250MNa3PO4 solution is 0.9375mol and 0.3125mol.

Explanation of Solution

The molarity of Na3PO4 solution is 0.250M.

The volume of Na3PO4 solution is 1.25L.

The number of moles of a solute present in the solution is given as,

n=MV

Where,

  • M represents molarity of the solution.
  • V represents the volume of the solution.

Substitute the value of molarity and volume of the Na3PO4 solution in the above equation.

n=0.250M1.25L1molL11M=0.3125mol

The number of moles of Na3PO4 present in the given solution is 0.3125mol.

The dissociation of Na3PO4 in water is represented as,

Na3PO4aq3Na+aq+PO43aq

One mole of Na3PO4 produces three moles of Na+ ions. Hence, 0.3125mol of Na3PO4 will produce 0.9375mol of Na+ ions.

One mole of Na3PO4 produces one mole of PO43 ions. Hence, 0.3125mol of Na3PO4 will produce 0.3125mol of PO43 ions.

Therefore, the number of moles of Na+ and PO43 ions present in 1.25L of 0.250MNa3PO4 solution is 0.9375mol and 0.3125mol.respectively.

Interpretation Introduction

(b)

Interpretation:

The number of moles of each ion present in 3.5mL of 6.0MH2SO4 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 120AP

The number of moles of H+ and SO42 ions present in 3.5mL of 6.0MH2SO4 solution is 0.042mol and 0.021mol respectively.

Explanation of Solution

The molarity of H2SO4 solution is 6.0M.

The volume of H2SO4 solution is 3.5mL.

The number of moles of a solute present in the solution is given as,

n=MV

Where,

  • M represents molarity of the solution.
  • V represents the volume of the solution.

Substitute the value of molarity and volume of the H2SO4 solution in the above equation.

n=6.0M3.5mL1L1000mL1molL11M=0.021mol

The number of moles of H2SO4 present in the given solution is 0.021mol.

The dissociation of H2SO4 in water is represented as,

H2SO4aq2H+aq+SO42aq

One mole of H2SO4 produces two moles of H+ ion. Hence, 0.021mol of H2SO4 will dissociate in 0.042mol of H+ ions.

One mole of H2SO4 produces one mole of SO42 ion. Hence, 0.021mol of H2SO4 will dissociate in 0.021mol of SO42 ions.

Therefore, the number of moles of H+ and SO42 ions present in 3.5mL of 6.0MH2SO4 solution is 0.042mol and 0.021mol respectively.

Interpretation Introduction

(c)

Interpretation:

The number of moles of each ion present in 25mL of 0.15MAlCl3 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 120AP

The number of moles of Al3+ and Cl ion present in 25mL of 0.15MAlCl3 solution is is 3.75×103mol and 1.125×102mol respectively.

Explanation of Solution

The molarity of AlCl3 solution is 0.15M.

The volume of AlCl3 solution is 25mL.

The number of moles of a solute present in the solution is given as,

n=MV

Where,

  • M represents molarity of the solution.
  • V represents the volume of the solution.

Substitute the value of molarity and volume of the AlCl3 solution in the above equation.

n=0.15M25mL1L1000mL1molL11M=3.75×103mol

The number of moles of AlCl3 present in the given solution is 3.75×103mol.

The dissociation of AlCl3 in water is represented as,

AlCl3aqAl3+aq+3Claq

One mole of AlCl3 produces one mole of Al3+ ion. Hence, 3.75×103mol of AlCl3 will dissociate in 3.75×103mol of Al3+ ions.

One mole of AlCl3 produces three moles of Cl ion. Hence, 3.75×103mol of AlCl3 will dissociate in 1.125×102mol of Cl ions.

Therefore, the number of moles of Al3+ and Cl ion present in 25mL of 0.15MAlCl3 solution is is 3.75×103mol and 1.125×102mol respectively.

Interpretation Introduction

(d)

Interpretation:

The number of moles of each ion present in 1.50L of 1.25MBaCl2 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 120AP

The number of moles of Ba2+ and Cl ion present in 1.50L of 1.25MBaCl2 solution is 1.875mol and 3.75mol respectively.

Explanation of Solution

The molarity of BaCl2 solution is 1.25M.

The volume of BaCl2 solution is 1.50L.

The number of moles of a solute present in the solution is given as,

n=MV

Where,

  • M represents molarity of the solution.
  • V represents the volume of the solution.

Substitute the value of molarity and volume of the BaCl2 solution in the above equation.

n=1.25M1.50L1molL11M=1.875mol

The number of moles of BaCl2 present in the given solution is 1.875mol.

The dissociation of BaCl2 in water is represented as,

BaCl2aqBa2+aq+2Claq

One mole of BaCl2 produces one mole of Ba2+ ions. Hence, 1.875mol of BaCl2 will dissociate in 1.875mol of Ba2+ ions.

One mole of BaCl2 produces two moles of Cl ions. Hence, 1.875mol of BaCl2 will dissociate in 3.75mol of Cl ions.

Therefore, the number of moles of Ba2+ and Cl ion present in 1.50L of 1.25MBaCl2 solution is 1.875mol and 3.75mol respectively.

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Chapter 15 Solutions

Introductory Chemistry: A Foundation

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