Chemistry: The Molecular Science
Chemistry: The Molecular Science
5th Edition
ISBN: 9781285199047
Author: John W. Moore, Conrad L. Stanitski
Publisher: Cengage Learning
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Chapter 15, Problem 84QRT

(a)

Interpretation Introduction

Interpretation:

The concentration of hydroxide ion has to be calculated at which magnesium hydroxide gets precipitated.

(a)

Expert Solution
Check Mark

Explanation of Solution

Given,

The concentration of Mg2+ is 0.050 M. Salts gets dissociation in to their ions, Mg(OH)2salt dissociate forms Mg2+ ion and 2OH- ions.

The dissociation of Mg(OH)2is given below,

    Mg(OH)2Mg2++2OH-

Solubility product constant (Ksp) is to be calculated for Mg(OH)2.

The Ksp value is calculated as follows,

  Ksp=[Mg2+]1[OH-]2Ksp=[Mg2+]1[OH-]2=1.8×10-11[OH-]2=1.8×10-11[Mg2+][OH-]=1.8×10-110.050M[OH-]=3.6×10-10[OH-]=1.897×10-5M

Therefore, Mg(OH)2starts to precipitated when the concentration of hydroxide ion is 1.897×10-5M.

(b)

Interpretation Introduction

Interpretation:

At concentration of hydroxide ion, other cation will get precipitated or not has to be determined.

(b)

Expert Solution
Check Mark

Explanation of Solution

Given,

  1. (1) The concentration of Na+ is 0.46 M. Salts gets dissociation in to their ions, NaOHsalt dissociate forms Na+ ion and OH- ions.

The dissociation of NaOHis given below,

    NaOHNa++OH-

Solubility product constant (Ksp) is so large for NaOH.

Therefore, when Ksp is large no precipitation will occur.

Given,

  1. (2) The concentration of Ca2+ is 0.01 M

Salts gets dissociation in to their ions, Ca(OH)2salt dissociate forms Ca2+ ion and 2OH- ions.

The dissociation of Ca(OH)2is given below,

    Ca(OH)2Ca2++2OH-

Solubility product constant (Ksp) is to be calculated for Ca(OH)2.

The Ksp value is calculated as follows,

  Ksp=[Ca2+]1[OH-]2Ksp=[Ca2+]1[OH-]2=5.5×10-6Where,Q=[Ca2+]1[OH-]2Q=(0.01M)(1.9×10-5M)2Q=3.61×10-12M

Solubility product constant (Ksp) is large for Ca(OH)2.

Therefore, when Ksp is large no precipitation will occur.

  1. (3) The concentration of Al3+ is 4×10-7 M

Salts gets dissociation in to their ions, Al(OH)3salt dissociate forms Al3+ ion and 3OH- ions.

The dissociation of Al(OH)3is given below,

    Al(OH)3Al3++3OH-

Solubility product constant (Ksp) is to be calculated for Al(OH)3.

The Ksp value is calculated as follows,

  Ksp=[Al3+]1[OH-]3Ksp=[Al3+]1[OH-]3=1.3×10-33Where,Q=[Al3+]1[OH-]3Q=(4×10-7 M)(1.9×10-5M)3Q=2.74×10-21M

Solubility product constant (Ksp) is smaller for Al(OH)3.

Therefore, when Ksp is small, precipitation will occur. Hence, Al(OH)3starts to precipitated.

  1. (4) The concentration of Fe2+ is 2×10-7 M

Salts gets dissociation in to their ions, Fe(OH)2salt dissociate forms Fe2+ ion and OH- ions.

The dissociation of Fe(OH)2is given below,

    Fe(OH)2Fe2++2OH-

Solubility product constant (Ksp) is to be calculated for Fe(OH)2.

The Ksp value is calculated as follows,

  Ksp=[Fe2+]1[OH-]2Ksp=[Fe2+]1[OH-]2=8.0×10-16Where,Q=[Fe2+]1[OH-]2Q=(2×10-7 M)(1.9×10-5M)2Q=7.22×10-17M

Solubility product constant (Ksp) is large for Fe(OH)2.

Therefore, when Ksp is large no precipitation will occur. In conclusion, the Solubility product constant (Ksp) is smaller for Al(OH)3. Precipitation will occur only for Al(OH)3.

(c)

Interpretation Introduction

Interpretation:

The percent has to be calculated when the other cation gets precipitated.

(c)

Expert Solution
Check Mark

Explanation of Solution

Given,

  1. (a) The concentration of Mg2+ is 0.050 M.  The enough hydroxide is added to precipitate 50% of the Mg2+.

Salts gets dissociation in to their ions, Mg(OH)2salt dissociate forms Mg2+ ion and 2OH- ions.

The dissociation of Mg(OH)2is given below,

    Mg(OH)2Mg2++2OH-

Solubility product constant (Ksp) is to be calculated for Mg(OH)2.

The Ksp value is calculated as follows,

Therefore, the concentration of Mg2+ is calculated as follows,

  Mg2+=(0.50M)×(0.050M)Mg2+=0.025M

  Ksp=[Mg2+]1[OH-]2Ksp=[Mg2+]1[OH-]2=1.8×10-11[OH-]2=1.8×10-11[Mg2+][OH-]=1.8×10-110.025M[OH-]=7.2×10-10[OH-]=2.68×10-5M

Therefore, Mg(OH)2starts to precipitated when the concentration of hydroxide ion is 2.68×10-5M.

  1. (b) Solubility product constant (Ksp) is so large for NaOH. Therefore, when the Ksp is large no precipitation will occur. Sodium ion does not for precipitated with NaOH, therefore, Na+ ion is zero percentage precipitated.
  2. (c) Solubility product constant (Ksp) is large for Ca(OH)2. Therefore, when the Ksp is large no precipitation will occur.
  3. (d) The concentration of Al3+ is 4×10-7 M. Salts gets dissociation in to their ions, Al(OH)3salt dissociate forms Al3+ ion and 3OH- ions.

The dissociation of Al(OH)3is given below,

    Al(OH)3Al3++3OH-

Solubility product constant (Ksp) is to be calculated for Al(OH)3.

The Ksp value is calculated as follows,

  Ksp=[Al3+]1[OH-]3Ksp=[Al3+]1[OH-]3=1.3×10-33Where,Q=[Al3+]1[OH-]3Q=(4×10-7 M)(2.7×10-5M)3Q=7.7×10-21M

Solubility product constant (Ksp) is smaller for Al(OH)3. Therefore, when the Ksp is small, precipitation will occur. Hence, Al(OH)3starts to precipitated.

The ICE table is given below,

  Al3+(aq)3OH-(aq)+Al(OH)3

Initial concentration 4×10-7 M2.7×10-5M0
Change -4×10-7 M-3(4×10-7 M)solid
Final conc.02.6×10-5Msolid

At equilibrium: Al(OH)3Al3++3OH-

The ICE table is given below,

  Al(OH)3Al3+(aq)+3OH-(aq)

Initial concentration solid02.6×10-5M
Change -x+x+x
At equilibrium.solid+x2.6×10-5M+x

At equilibrium: Al(OH)3Al3++3OH-

  Ksp=[Al3+]1[OH-]3Ksp=[Al3+]1[OH-]3=1.3×10-33

Where,

  [Al3+]1[OH-]3=1.3×10-33(x)(2.6×10-5M+x)3=1.3×10-33

Let consider x is small,

  (x)(2.6×10-5M)3=1.3×10-33(x)=1.3×10-33(2.6×10-5M)3(x)=[Al3+]=7.4×10-20

The concentration of Al3+ is given below,

  Concentartion of Al3+precipitated =  Initialconcentartion of Al3+-[Al3+]Concentartion of Al3+precipitated =  4.0×10-7-7.4×10-20MConcentartion of Al3+precipitated =  4.0×10-7M

Therefore,

  Percent dissociated =  dissociationinitial×100Percent dissociated =  4.0×10-7M 4.0×10-7M×100%Percent dissociated = 100%

The percentage of Al(OH)3 is 100%.

  1. (e) The concentration of Fe2+ is 2×10-7 M Salts gets dissociation in to their ions, Fe(OH)2salt dissociate forms Fe2+ ion and OH- ions.

The dissociation of Fe(OH)2is given below,

    Fe(OH)2Fe2++2OH-

Solubility product constant (Ksp) is to be calculated for Fe(OH)2.

The Ksp value is calculated as follows,

  Ksp=[Fe2+]1[OH-]2Ksp=[Fe2+]1[OH-]2=8.0×10-16

Where,

  Q=[Fe2+]1[OH-]2Q=(2×10-7 M)(2.7×10-5M)2Q=1.4×10-116M

Solubility product constant (Ksp) is large for Fe(OH)2.  Therefore, when Ksp is large no precipitation will occur.

In conclusion, Precipitation will occur only for Al(OH)3.Al(OH)3 shows 100% precipitation.

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Chapter 15 Solutions

Chemistry: The Molecular Science

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