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Chapter 10 Review, pages 678–683
Knowledge
1. (b)
2. (b)
3. (d)
4. (c)
5. (a)
6. (d)
7. False. In a galvanic cell, electrons travel from the anode to the cathode via the external
circuit.
8. True
9. True
10. False. The redox reaction in a secondary cell is reversible when a current runs
through the cell.
11. False. The rising cost of energy from gasoline has consumers looking at alternative
sources of energy.
12. False. Fusion is the nuclear process in which small atoms combine to form larger
atoms under conditions of very high temperature and pressure.
13. False. Steel rusts more quickly in salt water than in tap water.
14. False. Metals that readily corrode can often be protected by the application of a thin
coating of a metal that is more easily oxidized.
15. True
16. (a) (v)
(b) (iii)
(c) (vi)
(d) (viii)
(e) (iv)
(f) (i)
(g) (vii)
(h) (ii)
17. (a) Diagram of a galvanic cell produced using a silver electrode in a silver nitrate
solution and a copper electrode in a copper(II) nitrate solution:
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-2
(b) Anode (oxidation) half-reaction equation: Cu(s) → Cu2+(aq) + 2 e−
Cathode (reduction) half-reaction equation: Ag+(aq) + e− → Ag(s)
(c) Balance electrons by multiplying the half-reaction at the cathode by 2:
2 Ag+(aq) + 2 e− → 2 Ag(s)
Add the two half-reactions to give the balanced net ionic equation:
Cu(s) ! Cu 2+ (aq) + 2 e "
2 Ag + (aq) + 2 e " ! 2 Ag(s)
Cu(s) + 2 Ag + (aq) ! Cu 2+ (aq) + 2 Ag(s)
(d) Cu(s) | Cu2+(aq) | | Ag+(aq) | Ag(s)
18. (a) Oxidation occurs at the anode.
(b) The anode is the negative electrode.
19. In the reaction represented by the equation
Zn(s) + 2 Cu+(aq) → 2 Cu(s) + Zn2+(aq)
zinc metal, Zn(s), is the reducing agent and copper(I) ion, Cu+(aq), is the oxidizing agent.
20. During the operation of a galvanic cell, chemical energy is converted into electrical
energy.
21. (a) For the reaction in a galvanic cell represented by the net ionic equation
Fe2+(aq) + Al(s) → Al3+(aq) + Fe(s)
the standard line notation for the cell is
Al(s) | Al3+(aq) | | Fe2+(aq) | Fe(s)
(b) For the reaction in a galvanic cell represented by the net ionic equation
Cu2+(aq) + Cr2+(aq) → Cu+(aq) + Cr3+(aq) (using inert platinum electrodes)
the two half reactions are
Anode (oxidation) half-reaction equation: Cr3+(aq) + e → Cr2+(aq)
Cathode (reduction) half-reaction equation: Cu2+(aq) + 2 e– → Cu+(aq)
so the standard line notation for the cell is
Pt(s) | Cr2+(aq) | | Cu2+(aq) | Pt(s)
22. (a) Iron(II) ions are not capable of oxidizing chromium(II) ions to chromium(III) ions
because the standard reduction potential for iron(II) ions, –0.44 V, is less than the
standard reduction potential for chromium(II) ions, +0.50 V.
(b) Iron(II) ions are capable of oxidizing manganese, Mn, because the standard reduction
potential for iron(II) ions, –0.44 V, is greater than the standard reduction potential for
manganese ions, –1.18 V.
(c) Hydrogen gas, H2(g), cannot reduce nickel(II) ions, Ni2+(aq), because the standard
reduction potential for hydrogen gas, –0.83 V, is less than the standard reduction
potential for nickel(II) ions, –0.23 V.
23. (a) Hydrogen fuel cells are used in the U.S. space program.
(b) The product, electrical energy, was used to power NASA spacecraft.
24. Electrolysis occurs when direct current is passed through a cell containing two redox
active substances, causing a non-spontaneous redox reaction to occur.
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Chapter 10: Electrochemical Cells
10-3
25. Answers may vary. Sample answer: Three applications of electrolysis are:
galvanizing nails to make them weather resistant; plating precious metals like gold and
silver onto decorative metal objects; and aluminum recycling.
Understanding
26. (a) The salt bridge in a galvanic cell is a porous barrier between two half-cells with
different electrolytes. The salt bridge prevents the solutions from mixing but allows ions
to flow in both directions, to keep the solution in each half-cell electrically neutral. At the
anode, cations are produced and go into solution. This causes a buildup of positive ions in
this solution. If this electrical imbalance is not corrected, the reaction cannot continue.
The excess positive charge attracts the anions from the salt bridge, thereby keeping the
solution electrically neutral. At the cathode, the opposite occurs: as positive ions are
removed from solution, the solution becomes overly negative. This attracts the cations
from the salt bridge, keeping this side of the cell neutral.
(b) The purpose of the wire in a galvanic cell is to create an external circuit through
which electrons provided by the oxidation reaction at the anode can flow to the cathode,
the site of the reduction reaction.
(c) The purpose of the electrolyte in a galvanic cell is to act as an ionic conductor. The
two half-cells may use the same electrolyte, or they may use different electrolytes.
(d) The purpose of the conductive electrodes in a galvanic cell is to allow oxidation and
reduction to occur. The electrodes are the conductors by which the current leaves or
returns to the electrolyte. The anion provides electrons and the cathode accepts electrons.
27. A galvanic cell is an electrochemical cell that produces electrical energy from redox
reactions that occur spontaneously in the cell. Electrons move from the anode, which
undergoes oxidation, through a wire to the cathode, which undergoes reduction. The
solutions in which the electrodes are immersed complete the circuit by allowing electrons
to flow from the cathode to the anode.
The salt bridge, or porous substance in a fruit or vegetable, maintains the neutrality of the
solutions by allowing the flow of ions in or between the solutions. The electrical energy
produced can be measured by connecting an ammeter or a voltmeter along the wire
between the electrodes.
28.
Factors That Will Stop a Galvanic Cell from Functioning
Factor
Explanation
The anode is used up.
The anode is no longer able to donate
electrons to produce current.
The cations in the electrolytes are used
Current stops because electrons cannot
up.
move through the electrolyte.
The electrolyte in the salt bridge is used There is a buildup of charge in the halfup.
cells, so current stops.
The anions in the electrolytes are used
Current stops because electrons cannot
up.
move through the electrolyte.
29. (a) If a half-cell containing zinc metal in a zinc nitrate solution and a half-cell
containing nickel metal in a nickel nitrate solution were joined to form a galvanic cell, the
anode would be the zinc metal. The cathode would be the nickel metal.
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Chapter 10: Electrochemical Cells
10-4
(b) From Table 1 on page 646 of the textbook, the standard reduction potential for zinc is
−0.76 V, and the standard reduction potential for nickel is −0.23 V. Under standard
conditions, the cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= "0.23 V " ("0.76 V)
!E°r (cell) = 0.53 V
30. (a) To determine whether H+(aq) is capable of oxidizing Cu(s) to Cu2+(aq), look up
the equations for the two reduction half-cell reactions and their standard reduction
potentials in Table 1, Appendix B7:
2 H+(aq) + 2 e– → H2(g) !E°r = 0 V
Cu2+(aq) + 2 e– → Cu(s) !E°r = 0.34 V
H+(aq) cannot oxidize Cu(s) to Cu2+(aq) because the standard reduction potential for
hydrogen ions is less than the standard reduction potential for copper metal.
(b) To determine whether Fe3+(aq) is capable of oxidizing I−(aq), look up the equations
for the two reduction half-cell reactions and their standard reduction potentials in Table 1,
Appendix B7:
Fe3+(aq) + e– → Fe2+(aq) !E°r = 0.77 V
I2(s) + 2 e– → 2 I–(aq) !E°r = 0.54 V
Iron(III) ion can oxidize iodine ion because the standard reduction potential for iron(III)
ions is greater than the standard reduction potential for iodine ions.
(c) To determine whether H2(g) capable of reducing Ag+(aq), look up the equations for
the two reduction half-cell reactions and their standard reduction potentials in Table 1,
Appendix B7:
H2(g) + 2 e– → 2 H–(aq) !E°r = "2.23 V
Ag+(aq) + e– → Ag(s) !E°r = 0.80 V
H2(g) is capable of reducing Ag+(aq) because the standard reduction potential for
hydrogen gas is less than the standard reduction potential for silver ions (i.e., hydrogen is
a much stronger reducing agent than silver).
31. It is impossible to obtain the electric potential for a single half-cell because a half-cell
reaction cannot occur on its own.
32. The platinum wire in a standard hydrogen electrode functions as an inert electrode
that provides a surface on which redox reactions can occur, but it does not participate in
these reactions.
33. The equations for the half-reactions occurring at the electrodes when a half-cell
involving zinc metal and aqueous zinc ions is connected to a standard hydrogen electrode
are the following:
Anode half-reaction: Zn(s) → Zn2+(aq) + 2 e− !E°r = "0.76 V
Cathode half-reaction: 2 H+(aq) + 2 e− → H2(g) !E°r = 0 V
The hydrogen electrode has the more positive reduction potential, so it acts as the cathode
in this cell.
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Chapter 10: Electrochemical Cells
10-5
34. (a) Given: Zn2+(aq) + 2 e− → Zn(s) E°r = !0.76 V
Cd2+(aq) + 2 e− → Cd(s) E°r = !0.40 V
Required: !E°r (cell) and the net ionic equation for the cell reaction
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: The half-cell reaction with more positive potential is the reduction halfreaction. In this case, the reduction of cadmium ions occurs at the cathode:
Cd2+(aq) + 2 e− → Cd(s)
Zinc is oxidized at the anode. The equation for this half-cell reaction is written as an
oxidization reaction:
Zn(s) → Zn2+(aq) + 2 e−
The number of electrons is equal in both half-reaction equations, so add the equations for
two half-cell reactions to obtain the net ionic equation for this reaction:
Zn(s) + Cd2+(aq) → Cd(s) + Zn2+(aq)
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= "0.40 V " ("0.76 V)
!E°r (cell) = 0.36 V
Statement: The net ionic equation and standard cell potential for this cell are
Cd2+(aq) + Zn(s) → Cd(s) + Zn2+(aq)
and !E°r (cell) = 0.36 V .
(b) Given: Ag+(aq) + e− → Ag(s) E°r = 0.80 V
Al3+(aq) + 3 e− → Al(s) E°r = !1.66 V
Required: !E°r (cell) and the net ionic equation for the cell reaction
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: The half-cell reaction with more positive potential is the reduction halfreaction. In this case, the reduction of silver ions occurs at the cathode:
Ag+(aq) + e− → Ag(s)
Aluminum is oxidized at the anode. The equation for this half-cell reaction is written as
an oxidization reaction:
Al(s) → Al3+(aq) + 3 e−
To balance electrons in the two half-reactions, multiply the equation for the silver halfreaction by 3.
3 Ag+(aq) + 3 e− → 3 Ag(s)
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Chapter 10: Electrochemical Cells
10-6
Add the equations for the two half-cell reactions to obtain the net ionic equation for this
reaction:
3 Ag+(aq) + Al(s) → 3 Ag(s) + Al3+(aq)
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.80 V " ("1.66 V)
!E°r (cell) = 2.46 V
Statement: The net ionic equation and standard cell potential for this cell are
Al(s) + 3 Ag+(aq) → 3 Ag(s) + Al3+(aq)
and !E°r(cell) = 2.46 V.
(c) Given: Fe2+(aq) + 2 e− → Fe(s) E°r = !0.44 V
Al3+(aq) + 3 e− → Al(s) E°r = !1.66 V
Required: !E°r (cell) and the net ionic equation for the cell reaction
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: The half-cell reaction with more positive potential is the reduction halfreaction. In this case, the reduction of iron ions occurs at the cathode:
Fe2+(aq) + 2 e− → Fe(s)
Aluminum is oxidized at the anode. The equation for this half-cell reaction is written as
an oxidization reaction:
Al(s) → Al3+(aq) + 3 e−
To balance electrons in the two half-reactions, multiply the iron half-reaction equation by
3 and the aluminum half-reaction equation by 2.
3 Fe2+(aq) + 6 e− → 3 Fe(s)
2 Al(s) → 2 Al3+(aq) + 6 e−
Add the equations for the two half-cell reactions to obtain the net ionic equation for this
reaction:
3 Fe2+(aq) + 2 Al(s) → 3 Fe(s) + 2 Al3+(aq)
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= "0.44 V " ("1.66 V)
!E°r (cell) = 1.22 V
Statement: The net ionic equation and the standard cell potential for this cell are
3 Fe2+(aq) + 2 Al(s) → 3 Fe(s) + 2 Al3+(aq)
and !E°r (cell) = 1.22 V.
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Chapter 10: Electrochemical Cells
10-7
35. (a) Given: 2 H+(aq) + 2 e− → H2(g)
Al3+(aq) + 3 e− → Al(s)
Required: !E°r (cell) and the net ionic equation for the cell reaction
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: From Table 1, Appendix B7, the reduction potential for hydrogen is 0 V and
the reduction potential for aluminum is −1.66 V. The half-cell reaction with more
positive potential is the reduction half-reaction. In this case, the reduction of hydrogen
ions occurs at the cathode:
2 H+(aq) + 2 e− → H2(g)
Aluminum is oxidized at the anode. The equation for this half-cell reaction is written as
an oxidization reaction:
Al(s) → Al3+(aq) + 3 e−
To balance electrons in the two half-reactions, multiply the equation for the hydrogen
half-reaction by 3 and the aluminum half-reaction equation by 2.
6 H+(aq) + 6 e− → 3 H2(g)
2 Al(s) → 2 Al3+(aq) + 6 e−
Add the two half-cell reactions to obtain the net ionic equation for this reaction:
2 Al(s) + 6 H+(aq) → 3 H2(g) + 2 Al3+(aq)
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.00 V " ("1.66 V)
!E°r (cell) = 1.66 V
Statement: The net ionic equation and standard cell potential for this cell are
2 Al(s) + 6 H+(aq) → 2 Al3+(aq) + 3 H2(g)
and ΔE °r (cell) = 1.66 V.
(b) Given: Cr2O72−(aq) + 14 H+(aq) + 6 e− → 2 Cr3+(aq) + 7 H2O(l)
H2O2(aq) + 2 H+(aq) + 2 e− → 2 H2O(l)
Required: !E°r (cell) and the net ionic equation for the cell reaction
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
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Chapter 10: Electrochemical Cells
10-8
Solution: From Table 1, Appendix B7, the reduction potential for the dichromate ion is
+1.33 V and the reduction potential for hydrogen peroxide is +1.78 V. The half-cell
reaction with more positive potential is the reduction half-reaction. In this case, the
reduction of hydrogen peroxide occurs at the cathode:
H2O2(aq) + 2 H+(aq) + 2 e− → 2 H2O(l)
Dichromate ion is oxidized at the anode. The equation for this half-cell reaction is written
as an oxidization reaction:
2 Cr3+(aq) + 7 H2O(l) → Cr2O72−(aq) + 14 H+(aq) + 6 e−
To balance electrons in the two half-reactions, multiply the equation for the hydrogen
peroxide half-reaction by 3.
3 H2O2(aq) + 6 H+(aq) + 6 e− → 6 H2O(l)
Add the equations for the two half-cell reactions to obtain the net ionic equation for this
reaction:
2 Cr3+(aq) + 7 H2O(l) + 3 H2O2(aq) + 6 H+(aq) → Cr2O72−(aq) + 14 H+(aq) + 6 H2O(l)
Eliminate redundant hydrogen ions and water molecules.
2 Cr3+(aq) + H2O(l) + 3 H2O2(aq) → Cr2O72−(aq) + 8 H+(aq)
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= 1.78 V " 1.33 V
!E°r (cell) = 0.45 V
Statement: The net ionic equation and the standard cell potential for this cell are
2 Cr3+(aq) + H2O(l) + 3 H2O2(aq) → Cr2O72−(aq) + 8 H+(aq)
and !E°r (cell) = 0.45 V.
36. (a) Given: Pb2+(aq) + Cu(s) → Pb(s) + Cu2+(aq)
Required: !E°r (cell) and whether the reaction is spontaneous as written
Analysis: Use Table 1 in Appendix B7 to predict reaction spontaneity. Use the equation
!E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell potential.
Solution: Cathode half-reaction equation: Pb2+(aq) + 2 e− → Pb(s)
Anode half-reaction equation: Cu(s) → Cu2+(aq) + 2 e−
From Table 1, Appendix B7, the reduction potential for the lead(II) ion is −0.13 V and
the reduction potential for copper is +0.34 V.
The standard cell potential is:
!E°r (cell) = E°r (cathode) " E°r (anode)
= "0.13 V " 0.34 V
!E°r (cell) = "0.47 V
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Chapter 10: Electrochemical Cells
10-9
Statement: The standard cell potential for this cell is !E°r (cell) = "0.47 V . Because the
standard cell potential is negative, the reaction is not spontaneous.
(b) Given: Au3+(aq) + 3 Ag(s) → 3 Ag+(aq) + Au(s)
Required: !E°r (cell) and whether the reaction is spontaneous as written
Analysis: Use Table 1 in Appendix B7 to predict reaction spontaneity. Use the equation
!E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell potential.
Solution: Cathode half-reaction equation: Au3+(aq) + 3 e− → Au(s)
Anode half-reaction equation: Ag(s) → Ag+(aq) + e−
From Table 1, Appendix B7, the reduction potential for the gold is 1.50 V and the
reduction potential for silver is 0.80 V.
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= 1.50 V " 0.80 V
!E°r (cell) = 0.70 V
Statement: The standard cell potential for this cell is !E°r (cell) = 0.70 V . Because the
standard cell potential is positive, the reaction is spontaneous.
(c) Given: 2 Cu+(aq) → Cu(s) + Cu2+(aq)
Required: !E°r (cell) and whether the reaction is spontaneous as written
Analysis: Use Table 1 in Appendix B7 to predict reaction spontaneity. Use the equation
!E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell potential.
Solution: Cathode half-reaction equation: Cu+(aq) + e− → Cu(s)
Anode half-reaction equation: Cu+(aq) → Cu2+(aq) + e−
From Table 1, Appendix B7, the reduction potential for the copper(I) ion is 0.52 V and
the reduction potential for copper(II) ion is 0.16 V.
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.52 V " 0.16 V
!E°r (cell) = 0.36 V
Statement: The standard cell potential for this cell is !E°r (cell) = 0.36 V . Because the
standard cell potential is positive, the reaction is spontaneous.
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-10
37. (a) Given: MnO4−(aq) + I−(aq) → I2(s) + Mn2+(aq)
Required: !E°r (cell) , whether the reaction is spontaneous as written, and the balanced
equation in acid
Analysis: Use Table 1 in Appendix B7 to predict reaction spontaneity. Use the equation
!E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell potential.
Solution: Manganese gains 5 electrons and iodine loses 1 electron. Therefore, manganese
is reduced and iodine is oxidized.
Cathode half-reaction equation: MnO4−(aq) + 5 e− → Mn2+(aq)
Anode half-reaction equation: 2 I−(aq) → I2(aq) + 2 e−
From Table 1, Appendix B7, the reduction potential for the permanganate ion is 1.51 V
and the reduction potential for iodine is 0.54 V.
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= 1.51 V " 0.54 V
!E°r (cell) = 0.97 V
To balance the equation in acid, first balance electrons by multiplying the equation for
the permanganate ion half-reaction by 2 and the iodine half-reaction equation by 5:
2 MnO4−(aq) + 10 e− → 2 Mn2+(aq)
10 I−(aq) → 5 I2(aq) + 10 e−
Add the half-reaction equations:
2 MnO4−(aq) + 10 I−(aq) → 2 Mn2+(aq) + 5 I2(aq)
Balance oxygen atoms by adding water.
2 MnO4−(aq) + 10 I−(aq) → 2 Mn2+(aq) + 5 I2(aq) + 8 H2O(l)
Balance hydrogen atoms by adding hydrogen ions.
2 MnO4−(aq) + 10 I−(aq) + 16 H+(aq) → 2 Mn2+(aq) + 5 I2(aq) + 8 H2O(l)
Statement: The standard cell potential for this cell is !E°r (cell) = 0.97 V . Because the
standard cell potential is positive, the reaction is spontaneous. The balanced equation in
acid is
2 MnO4−(aq) + 10 I−(aq) + 16 H+(aq) → 2 Mn2+(aq) + 5 I2(aq) + 8 H2O(l).
(b) Given: MnO4−(aq) + F−(aq) → F2(g) + Mn2+(aq)
Required: !E°r (cell) , whether the reaction is spontaneous as written, and the balanced
equation in acid
Analysis: Use Table 1 in Appendix B7 to predict reaction spontaneity. Use the equation
!E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell potential.
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-11
Solution: Manganese gains 5 electrons and fluorine loses 1 electron. Therefore,
manganese is reduced and fluorine is oxidized.
Cathode half-reaction equation: MnO4−(aq) + 5 e− → Mn2+(aq)
Anode half-reaction equation: 2 F−(aq) → F2(g) + 2 e−
From Table 1, Appendix B7, the reduction potential for the permanganate ion is 1.51 V
and the reduction potential for fluorine is 2.87 V.
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= 1.51 V " 2.87 V
!E°r (cell) = "1.36 V
To balance the equation in acid, first balance electrons by multiplying the equation for
the permanganate ion half-reaction by 2 and the fluorine half-reaction equation by 5:
2 MnO4−(aq) + 10 e− → 2 Mn2+(aq)
10 F−(aq) → 5 F2(g) + 10 e−
Add the half-reaction equations:
2 MnO4−(aq) + 10 F−(aq) → 2 Mn2+(aq) + 5 F2(g)
Balance oxygen atoms by adding water.
2 MnO4−(aq) + 10 F−(aq) → 2 Mn2+(aq) + 5 F2(g) + 8 H2O(l)
Balance hydrogen atoms by adding hydrogen ions.
2 MnO4−(aq) + 10 F−(aq) + 16 H+(aq) → 2 Mn2+(aq) + 5 F2(g) + 8 H2O(l)
Statement: The standard cell potential for this cell is !E°r (cell) = "1.36 V . Because the
standard cell potential is negative, the reaction is not spontaneous. The balanced equation
in acid is
2 MnO4−(aq) + 10 F−(aq) + 16 H+(aq) → 2 Mn2+(aq) + 5 F2(g) + 8 H2O(l).
38. (a) The electrolyte in a typical alkaline dry cell is potassium hydroxide.
(b) The electrolytes of alkaline dry cells are corrosive. When handling a corroded
alkaline dry cell I would recommend wearing gloves to prevent your skin coming into
contact with the electrolytes.
39. (a) The two substances that must always be present for rusting to occur are oxygen
and water.
(b) Rust forms more readily in a damp environment than in dry conditions because water
is needed to complete the cathode half-cell reaction with oxygen as follows:
O2(g) + 2 H2O(l) + 4 e– → 4 OH–(aq)
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Chapter 10: Electrochemical Cells
10-12
40. Examples may vary. Sample answer:
41. (a) Since aluminum is a light metal, its use instead of steel for automobile parts will
decrease the mass of the automobile, resulting in increased fuel efficiency.
(b) One positive impact on the environment of using aluminum instead of steel for
automobile parts is a decrease in the greenhouse gas emissions from automobiles, since
less fuel will be used to drive the same distance. Two negative impact on the environment
are the increase in greenhouse gas production and the release of toxic ions and metals in
the production and purification of aluminum.
42. (a) When molten potassium fluoride, KF(s), is electrolyzed using inert electrodes:
Anode half-reaction equation: 2 F–(l) → F2(g) + 2 e–
Cathode half-reaction equation: 2 K+(l) + 2 e– → 2 K(l)
(b) When molten copper(II) chloride, CuCl2(s), is electrolyzed using inert electrodes:
Anode half-reaction equation: 2 Cl–(l) → Cl2(g) + 2 e–
Cathode half-reaction equation: Cu2+ + 2 e– → Cu(l)
(c) When molten magnesium iodide, MgI2(s), is electrolyzed using inert electrodes:
Anode half-reaction equation: 2 I–(l) → I2(l) + 2 e–
Cathode half-reaction equation: Mg2+(l) + 2 e– → Mg(l)
Analysis and Application
43. Answers may vary. Sample answers:
(a) A potential difference of 1.2 V could be supplied by a galvanic cell consisting of
chlorine gas and copper ions.
(b) Cathode half-reaction equation: Cl2(g) + 2 e− → 2 Cl−(aq)
Anode half-reaction equation: Cu+(aq) → Cu2+(aq) + e−
E°r = 1.36 V
E°r = 0.16 V
!E°r (cell) = E°r (cathode) " E°r (anode)
= 1.36 V " 0.16 V
!E°r (cell) = 1.20 V
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Chapter 10: Electrochemical Cells
10-13
(c) Line notation for the cell: Pt(s) | Cu2+(aq) | | Cl−(aq) | Pt(s)
44. (a) The student could build galvanic cells using 6 combinations of 2 electrodes—
Ag−Zn, Ag−Cu, Ag−Sn, Zn−Cu, Zn−Sn, Cu−Sn—and their corresponding electrolytes
and compare their potential differences.
(b) To carry out this task, the student would require 4 beakers for the electrolytes, a
U-tube and cotton plugs for a salt bridge, a connecting wire with alligator clips, and a
voltmeter to measure the potential difference.
(c) Sketch of the setup necessary to determine experimentally which combination of
metal strips and solutions will produce the maximum potential difference:
Silver nitrate will be a source of Ag+ ions, so from Table 1 in Appendix B7, the standard
reduction potential for the copper metal strip will be E°r = +0.80 V.
Zinc nitrate will be a source of Zn2+ ions, so from Table 1 the standard reduction
potential for the copper metal strip will be E°r = !0.76 V.
Copper(II) nitrate will be a source of Cu2+ ions, so from Table 1 the standard reduction
potential for the copper metal strip will be E°r = +0.34 V.
Tin(II) nitrate will be a source of Sn2+ ions, so from Table 1 the standard reduction
potential for the copper metal strip will be E°r = !0.14 V.
Based on these values, the greatest cell potential would be achieved by using the metals
that have the greatest potential difference, resulting in the highest positive number for
!E°r (cell) , that is, by using silver as the cathode and zinc as the anode. The resulting
standard cell potential would be
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.80 V " ("0.76 V)
!E°r (cell) = 1.56 V
45. (a) Given: Ag(s), Ag+(aq), Fe2+(aq), Pt(s)
Required: balanced ionic equation, !E°r (cell)
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-14
Solution: From Table 1 in Appendix B7, the half-reaction equations and standard
reduction potentials are
Ag+(aq) + e− → Ag(s) E°r = 0.80 V
Fe3+(aq) + e− → Fe2+(aq) E°r = 0.77 V
The half-cell reaction with more positive potential is the reduction half-reaction. In this
case, the reduction of silver ion occurs at the cathode:
Ag+(aq) + e− → Ag(s)
Iron(II) ion is oxidized at the anode. The equation for this half-cell reaction is written as
an oxidization reaction:
Fe2+(aq) → Fe3+(aq) + e−
The net ionic equation is
Ag+(aq) + Fe2+(aq) → Fe3+(aq) + Ag(s)
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.80 V " 0.77 V
!E°r (cell) = 0.03 V
Statement: The net ionic equation for this reaction is
Ag+(aq) + Fe2+(aq) → Fe3+(aq) + Ag(s)
The standard cell potential is !E°r (cell) = 0.03 V.
(b) Given: Au(s), Au3+(aq), Cu+(aq), Cu2+(aq), Pt(s)
Required: balanced ionic equation, !E°r (cell)
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: From Table 1 in Appendix B7, the half-reaction equations and standard
reduction potentials are
Au3+(aq) + 3 e− → Au(s) E°r = 1.50 V
Cu2+(aq) + e− → Cu+(aq)
E°r = 0.16 V
The half-cell reaction with more positive potential is the reduction half-reaction. In this
case, the reduction of gold ion occurs at the cathode:
Au3+(aq) + 3 e− → Au(s)
Copper(I) ion is oxidized at the anode. The equation for this half-cell reaction is written
as an oxidization reaction:
Cu+(aq) → Cu2+(aq) + e−
To balance electrons, multiply the equation for the oxidation reaction by 3:
3 Cu+(aq) → 3 Cu2+(aq) + 3 e−
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-15
The net ionic equation is
Au3+(aq) + 3 Cu+(aq) → 3 Cu2+(aq) + Au(s)
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= 1.50 V " 0.16 V
!E°r (cell) = 1.34 V
Statement: The net ionic equation for this reaction is
Au3+(aq) + 3 Cu+(aq) → 3 Cu2+(aq) + Au(s)
The standard cell potential is !E°r (cell) = 1.34 V.
(c) Given: Cd(s), Cd2+(aq), VO2+(aq), H+(aq), Pt(s)
Required: balanced ionic equation, !E°r (cell)
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: From Table 1 in Appendix B7, the half-reaction equations and standard
reduction potentials are
Cd2+(aq) + 2 e− → Cd(s) E°r = !0.40 V
VO2+(aq) + 2 H+(aq) + e− → VO2+(aq) + H2O(l) E°r = 1.00 V
The half-cell reaction with more positive potential is the reduction half-reaction. In this
case, the reduction of VO2+(aq) occurs at the cathode:
VO2+(aq) + 2 H+(aq) + e− → VO2+(aq) + H2O(l)
Cadmium is oxidized at the anode. The equation for this half-cell reaction is written as an
oxidization reaction:
Cd(s) → Cd2+(aq) + 2 e−
To balance electrons, multiply the equation for the reduction reaction by 2:
2 VO2+(aq) + 4 H+(aq) + 2 e− → 2 VO2+(aq) + 2 H2O(l)
The net ionic equation is
Cd(s) + 2 VO2+(aq) + 4 H+(aq) → Cd2+(aq) + 2 VO2+(aq) + 2 H2O(l)
The standard cell potential is
!E°r (cell) = E°r (cathode) " E°r (anode)
= 1.00 V " ("0.40 V)
!E°r (cell) = 1.40 V
Statement: The net ionic equation for this reaction is
Cd(s) + 2 VO2+(aq) + 4 H+(aq) → Cd2+(aq) + 2 VO2+(aq) + 2 H2O(l)
The standard cell potential is !E°r (cell) = 1.40 V.
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-16
46. (a) Given: IO3−(aq) + Fe2+(aq) → Fe3+(aq) + I2(aq)
Required: sketch of cell, balanced equation, !E°r (cell)
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: From Table 1 in Appendix B7 and the given unbalanced equation, the halfreaction equations and standard reduction potentials are
IO3−(aq) + 6 H+(aq) + 5 e−→
1
I2(s) E°r = 1.20 V
2
Fe2+(aq) → Fe3+(aq) + e− E°r = 0.77 V
The iodate ion half-reaction has the more positive reduction potential, so iodate ion is
reduced at the cathode and iron(II) ion is oxidized at the anode.
To balance electrons, multiply the equation for the iron(II) ion half-reaction by 5.
5 Fe2+(aq) → 5 Fe3+(aq) + 5 e−
Add the two half-reaction equations.
IO3−(aq) + 6 H+(aq) + 5 Fe2+(aq) →
1
I2(s) + 5 Fe3+(aq)
2
Add water to balance oxygen atoms.
1
I2(s) + 5 Fe3+(aq) + 3 H2O(l)
2
Multiply all entities by 2 to obtain the net ionic equation.
2 IO3−(aq) + 12 H+(aq) + 10 Fe2+(aq) → I2(s) + 10 Fe3+(aq) + 6 H2O(l)
IO3−(aq) + 6 H+(aq) + 5 Fe2+(aq) →
!E°r (cell) = E°r (cathode) " E°r (anode)
= 1.20 V " 0.77 V
!E°r (cell) = 0.43 V
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-17
Statement: The net ionic equation for this cell is
2 IO3−(aq) + 12 H+(aq) + 10 Fe2+(aq) → I2(s) + 10 Fe3+(aq) + 6 H2O(l).
The standard cell potential is !E°r (cell) = 0.43 V.
(b) Given: Zn(s) + Ag+(aq) → Zn2+(aq) + Ag(s)
Required: sketch of cell, balanced equation, !E°r (cell)
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: From Table 1 in Appendix B7 and the given unbalanced equation, the halfreaction equations and standard reduction potentials are
Zn(s) → Zn2+(aq) + 2 e− E°r = !0.76 V
Ag+(aq) + e− → Ag(s) E°r = +0.80 V
The silver ion half-reaction has the more positive reduction potential, so silver ion is
reduced at the cathode and zinc is oxidized at the anode.
To balance electrons, multiply the equation for the silver half-reaction by 2.
2 Ag+(aq) + 2 e− → 2 Ag(s)
Add the two half-reaction equations to obtain the net ionic equation.
Zn(s) + 2 Ag+(aq) → Zn2+(aq) + 2 Ag(s)
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.80 V " ("0.76 V)
!E°r (cell) = 1.56 V
Statement: The net ionic equation for this cell is
Zn(s) + 2 Ag+(aq) → Zn2+(aq) + 2 Ag(s).
The standard cell potential is !E°r (cell) = 1.56 V.
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-18
47. (a) Given: !E°r (cell) = 2.00 V , Cu(s), Cu(NO3)2(aq)
Required: identity of metal
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the reduction
potential of the unknown metal.
Solution: From Table 1 in Appendix B7, the half-reaction equation and reduction
potential for copper metal are
Cu2+(aq) + 2 e− → Cu(s) E°r = 0.34 V
The standard cell potential and the reduction potential of copper are both positive, so
copper must be the cathode.
!E°r (cell) = E°r (cathode) " E°r (anode)
E°r (anode) = E°r (cathode) " !E°r (cell)
= 0.34 V " 2.00 V
E°r (anode) = "1.66 V
From Table 1, the unknown metal is aluminum.
Statement: The unknown metal is aluminum.
(b) The half-reaction equation for aluminum is
Al3+(aq) + 3 e− → Al(s)
This reaction occurs at the anode, so it is written as an oxidation reaction.
Al(s) → Al3+(aq) + 3 e−
To balance electrons, multiply equation for the copper half-reaction by 3 and the
aluminum half-reaction equation by 2.
3 Cu2+(aq) + 6 e− → 3 Cu(s)
2 Al(s) → 2 Al3+(aq) + 6 e−
Add the two half-reaction equations. The net ionic equation is
3 Cu2+(aq) + 2 Al(s) → 2 Al3+(aq) + 3 Cu(s)
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-19
48. The half-reactions and reduction potentials of the given entities (in boldface) are
!!
Na+(aq) + e– #
E°r = –2.71 V
!"
! Na(s)
–
!!
Cl2(g) = 2 e– #
!"
! 2 Cl (aq)
E°r = 1.36 V
!!
Ag+(aq) + e– #
!"
! Ag(s)
E°r = 0.80 V
!!
Zn2+(aq) + 2 e– #
!"
! Zn(s)
E°r = !0.76 V
!!
Pb2+(aq) + 2 e– #
E°r = !0.13 V
!"
! Pb(s)
Arrange the half-reactions in order of decreasing strength of oxidizing agents.
–
!!
Cl2(g) = 2 e– #
!"
! 2 Cl (aq) E°r = 1.36 V
!!
Ag+(aq) + e– #
!"
! Ag(s)
E°r = 0.80 V
!!
Pb2+(aq) + 2 e– #
!"
! Pb(s)
E°r = !0.13 V
!!
Zn2+(aq) + 2 e– #
!"
! Zn(s)
E°r = !0.76 V
!!
Na+(aq) + e– #
E°r = –2.71 V
!"
! Na(s)
(a) The strongest oxidizing agent is silver ion, Ag+(aq), because it appears highest in the
table of reduction potentials on the reactant side of the equation.
(b) The strongest reducing agent is zinc metal, Zn(s), because it appears lowest in the
table of reduction potentials on the product side of the equation.
(c) The reduction potential of SO42–(aq) is 0.20 V, so the entities that can be oxidized by
sulfate ions in acid are lead metal, Pb(s), and zinc metal, Zn(s), because they appear
lower than sulfate ions on the product side of the equation.
(d) The reduction potential of aluminum metal, Al(s), is –1.66 V, so Ag+(aq), and zinc
ion, Zn2+(aq) can be reduced by aluminum metal, because they appear above aluminum
metal in the table of reduction potentials on the reactant side of the equation.
49. The half-reactions and reduction potentials of the given entities (in boldface) are
Br–(aq), Br2(g), H+(aq), H2(g), La3+(aq), Ca(s), Cd(s)
−
!!
Br2(l) + 2 e− #
E°r = 1.09 V
!"
! 2 Br (aq)
!!
2 H+(aq) + 2 e– #
!"
! H2(g)
E°r = 0 V
!!
La3+(aq) + 3 e– #
!"
! La(s)
E°r = !2.37 V
!!
Ca2+(aq) + 2 e– #
!"
! Ca(s)
E°r = !2.76 V
!!
Cd2+(aq) + 2 e– #
E°r = !0.40 V
!"
! Cd(s)
Arrange the half-reactions in order of decreasing strength of oxidizing agents.
−
!!
Br2(l) + 2 e− #
E°r = 1.09 V
!"
! 2 Br (aq)
!!
2 H+(aq) + 2 e– #
!"
! H2(g)
E°r = 0 V
!!
Cd2+(aq) + 2 e– #
!"
! Cd(s)
E°r = !0.40 V
!!
La3+(aq) + 3 e– #
!"
! La(s)
E°r = !2.37 V
!!
Ca2+(aq) + 2 e– #
!"
! Ca(s)
E°r = !2.76 V
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-20
(a) The strongest oxidizing agent is Br2(l) because it appears highest in the table of
reduction potentials on the reactant side of the equation.
(b) The strongest reducing agent is Ca(s) because it appears lowest in the table of
reduction potentials on the product side of the equation.
(c) The reduction potential of MnO4–(aq) is 1.68 V, so the entities that can be oxidized by
permanganate ions in acid are Br−(aq), H2(g), Cd(s), and Ca(s) because they appear lower
than permanganate ions on the product side of the equation.
(d) The reduction potential of zinc metal, Zn(s), is –0.76 V, so the entities that can be
reduced by zinc metal are H+(aq) and Br2(l), because they appear above zinc metal in the
table of reduction potentials on the reactant side of the equation.
50. Answers may vary. Sample answers:
(a) A reagent that, at SATP in acidic solution, will oxidize bromide ions to bromine gas,
Br2(g), but not oxidize chloride ions to chloride gas is Cr2O72– (aq).
(b) A reagent that, at SATP in acidic solution, will oxidize magnesium to magnesium(II)
ions, but not oxidize iron to iron(II) ions is Zn2+(aq).
(c) A reagent that, at SATP in acidic solution, will reduce copper(II) ions to copper metal,
but not to copper(I) ions is Ag(s), Cl–(aq).
51. (a) Given: Cu2+(aq) + 2 e− → Cu(s) E°r (SCE) = 0.242 V
Required: !E°r (cell) , and whether SCE is the cathode or the anode
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: From Table 1 in Appendix B7, the reduction potential for copper(II) ions is
0.34 V. This reduction potential is more positive than the reduction potential for SCE;
therefore, copper ion is reduced at the cathode and SCE is oxidized at the anode.
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.34 V " 0.242 V
!E°r (cell) = 0.098 V = 0.10 V
Statement: SCE is the anode in this cell. The standard reduction potential of this cell is
!E°r (cell) = 0.10 V.
(b) Given: Fe3+(aq) + e− → Fe2+(aq) E°r (SCE) = 0.242 V
Required: !E°r (cell) , and whether SCE is the cathode or the anode
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-21
Solution: From Table 1 in Appendix B7, the reduction potential for iron(III) ions is
0.77 V. This reduction potential is more positive than the reduction potential for SCE;
therefore, iron(III) ion is reduced at the cathode and SCE is oxidized at the anode.
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.77 V " 0.242 V
!E°r (cell) = 0.53 V
Statement: SCE is the anode in this cell. The standard reduction potential of this cell is
!E°r (cell) = 0.53 V.
(c) Given: AgCl(aq) + e− → Ag(s) + Cl−(aq) E°r (SCE) = 0.242 V
Required: !E°r (cell) , and whether SCE is the cathode or the anode
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: From Table 1 in Appendix B7, the reduction potential for chloride ions is
0.22 V. This reduction potential is less positive than the reduction potential for SCE;
therefore, chloride ion is oxidized at the anode and SCE is reduced at the cathode.
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.242 V " 0.22 V
!E°r (cell) = 0.02 V
Statement: SCE is the cathode in this cell. The standard reduction potential of this cell is
!E°r (cell) = 0.02 V.
(d) Given: Al3+(aq) + 3 e− → Al(s) E°r (SCE) = 0.242 V
Required: !E°r (cell) , and whether SCE is the cathode or the anode
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: From Table 1 in Appendix B7, the reduction potential for aluminum ions is
−1.66 V. This reduction potential is less positive than the reduction potential for SCE;
therefore, aluminum ion is oxidized at the anode and SCE is reduced at the cathode.
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.242 V " ("1.66 V)
!E°r (cell) = 1.90 V
Statement: SCE is the cathode in this cell. The standard reduction potential of this cell is
!E°r (cell) = 1.90 V.
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-22
(e) Given: Ni2+(aq) + 2 e− → Ni(s) E°r (SCE) = 0.242 V
Required: !E°r (cell) , and whether SCE is the cathode or the anode
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: From Table 1 in Appendix B7, the reduction potential for nickel(II) ions is
−0.23 V. This reduction potential is less positive than the reduction potential for SCE;
therefore, nickel(II) ion is oxidized at the anode and SCE is reduced at the cathode.
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.242 V " ("0.23 V)
!E°r (cell) = 0.47 V
Statement: SCE is the cathode in this cell. The standard reduction potential of this cell is
!E°r (cell) = 0.47 V.
52. (a) Given: 2 NaClO2(aq) + Cl2(g) → 2 ClO2(g) + 2 NaCl(aq)
Required: !E°r (cell) for the production of ClO2(g)
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: From Table 1 in Appendix B7, the half-reaction equations and reduction
potentials for chlorine gas and chlorine dioxide gas are
Cl2(g) + 2 e− → 2 Cl−(aq) E°r = 1.36 V
ClO2(g) + e− → ClO2−(aq) E°r = 0.954 V
The chlorine gas half-reaction has the more positive reduction potential, so chlorine gas is
reduced at the cathode and chlorine dioxide is oxidized at the anode.
!E°r (cell) = E°r (cathode) " E°r (anode)
= 1.36 V " 0.954 V
!E°r (cell) = 0.41 V
Statement: The standard cell potential for the production of chlorine dioxide gas is
0.41 V.
(b) Electrolysis is not required for the production of chlorine dioxide gas because the
standard cell potential is a positive value, so the reaction is spontaneous.
53. When jump starting a dead battery, the ground jumper connection should be attached
to a remote part of the engine block so that any spark that is produced when the cable is
disconnected will not cause the battery to explode. The reaction in the battery when
starting produces gaseous hydrogen and oxygen, which can ignite in the presence of a
spark.
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-23
54. Both fusion and fission are nuclear reactions that release huge amounts of energy;
however, fusion has two significant advantages. While fission produces radioactive
products, the products of fusion are not radioactive or toxic. While fission relies on fuels
such as uranium, fusion uses readily available hydrogen as a fuel. Fusion also has one
very significant disadvantage—it only occurs at very high temperatures, which
researchers have not yet succeeded in reproducing in a format that could be used for
commercial energy generation.
55. The dissolved carbon dioxide in natural water affects the rusting of metallic iron as
follows: the hydrogen ions in dissolved carbon dioxide acidify the water, which results in
rusting of metallic iron occurring more quickly.
56. When iron rusts it loses electrons. Galvanized nails have a zinc coating that forms a
protective barrier between the air and the iron nail. Galvanized nails will not rust because
zinc holds its electrons more loosely than iron does, so it will donate electrons instead of
iron. In this way, zinc prevents the rusting of the nails. Ungalvanized nails exposed to the
elements will begin to rust.
The iron nails hammered through the aluminum siding did not rust because aluminum
donated electrons instead of iron so, like the zinc on the galvanized nails, the aluminum
prevented the rusting of the nails.
57. (a) Answers may vary. Sample answer: The metals that rarely corrode in air include
gold, platinum, and silver. These are called the noble metals because people recognized
that they were unreactive and suitable for use in highly esteemed products such as coins
and jewellery.
(b) Answers may vary. Sample answer: The noble metals do not generally corrode
because they have stable electron orbitals with full d orbitals.
58. Sterling silver corrodes more readily than pure silver or gold because it contains
copper. The reduction potential of copper ( E°r = +0.34 V) is lower than that of silver
( E°r = +0.80 V) and of gold ( E°r = +0.1.50 V).
59. A balanced chemical equation for the reaction of gold in aqua regia is the following:
Au(s) + HNO3(aq) + 4 HCl(aq) → AuCl4–(aq) + NO(g) + 2 H2O(l) + H+(aq)
60. (a) When 1.0 mol/L nickel bromide solution, NiBr2(aq) is used in an electrolytic cell:
Anode half-reaction equation: 2 Br–(aq) → Br2(g) + 2 e–
Cathode half-reaction equation: Ni2+(aq) + 2 e– → Ni(s)
The reaction would result in the metal being plated with nickel.
(b) When 1.0 mol/L aluminum fluoride solution, AlF3(aq) is used in an electrolytic cell:
Anode half-reaction equation: 2 F–(aq) → F2(g) + 2 e–
Cathode half-reaction equation: Al3+(aq) + 3 e– → Al(s)
The reaction would result in the metal being plated with aluminum.
(c) When 1.0 mol/L manganese iodide solution, MnI2(aq) is used in an electrolytic cell:
Anode half-reaction equation: 2 I–(aq) → I2(l) + 2 e–
Cathode half-reaction equation: Mn2+(aq) + 2 e– → Mn(s)
The reaction would result in the metal being plated with manganese.
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-24
Evaluation
61. Given: ClO−(aq) + H2O(l) + 2 e− → 2 OH−(aq) + Cl−(aq) E°r = 0.90 V
N2H4(aq) + 2 H2O(l) + 2 e− → 2 NH3(g) + 2 OH−(aq) E°r = !0.10 V
Required: !E°r (cell)
Analysis: Use the equation !E°r (cell) = E°r (cathode) " E°r (anode) to calculate the standard cell
potential.
Solution: Determine whether mixing the given solutions results in a spontaneous
reaction. Since the reduction potential for hypochlorite ion is more positive than the
reduction potential for hydrazine, the reduction of hypochlorite ions occurs at the cathode
and hydrazine is oxidized at the anode.
!E°r (cell) = E°r (cathode) " E°r (anode)
= 0.90 V " ("0.10 V)
!E°r (cell) = 1.00 V
The standard cell potential is a positive value, so the reaction is spontaneous.
Statement: Since combining hydrazine with hypochlorite ion results in a spontaneous
reaction, mixing household bleach (a solution of sodium hypochlorite, NaClO(aq)) with
household ammonia or glass cleaners that contain ammonia is not safe.
62. According to the redox table, the half-reaction equation associated with the reaction
of mercury metal with stomach acid is:
Hg2Cl2(aq) + 2 e− → 2 Hg(l) + 2 Cl−(aq) E°r = 0.34 V
The positive reduction potential indicates that this half-reaction is spontaneous in the
forward direction, which means that it is non-spontaneous in the reverse direction. From
this result, we can conclude that the reaction of mercury metal with stomach acid is not a
spontaneous reaction, so swallowing dental fillings containing elemental mercury poses
minimal health risks, as asserted by the Canadian Dental Association.
63. Answers will vary. Sample answer: Although the scientific meaning of the word
“battery” is quite different from its everyday use, I don’t think that the scientific
definition of a battery should be changed, because the term is the accepted term in
science and has been in use for hundreds of years. There are many terms in everyday
language that are used inaccurately. Studying science teaches us the correct meaning of
these terms.
64. (a) Corrosion is an example of an galvanic process. (It is spontaneous.)
(b) The corrosion of steel involves the oxidation of iron coupled with the reduction of
oxygen.
(c) Steel rusts more easily in humid climates than in dry ones. This is correct.
(d) Salting roads in the winter has the added cost of increasing the corrosion of steel.
(The salts in solution act as electrolytes.)
(e) The key to cathodic protection is to connect a metal more easily oxidized than iron to
the surface to be protected. This is correct.
Copyright © 2012 Nelson Education Ltd.
Chapter 10: Electrochemical Cells
10-25
65. Answers may vary. Sample answer: Place four steel strips in shallow pools of salt
water. Before doing this, galvanize one with zinc, attach one to a block of zinc by an
electrode, and apply a DC current to one. The fourth will act as a control. Allow the steel
strips to sit for two days, then observe and record the amount of corrosion on each strip.
Clean the steel strips, remove any corrosion, and determine the mass of each strip. If the
methods are as effective as I predict they will be, the control will have the most corrosion
and will be the lightest. The galvanized strip will have no visible rust but may have
additional mass from zinc oxides that formed, likely the most effective protection. The
steel attached to a block of zinc will not change mass and will show only minor signs of
corrosion. The impressed current strip will have reduced corrosion compared to the
control.
Materials required: four steel strips, four shallow non-reactive containers, salt water, zinc
to galvanize, zinc block, electrolytic cell, source of DC current, balance.
66. (a) Pure aluminum is difficult to produce because it is difficult to extract from the
aluminum oxides found in bauxite ore. The Hall-Héroult process uses molten cryolite,
Na3AlF6(l), as a solvent for the aluminum oxide.
(b) The Hall-Héroult process made it less expensive to produce aluminum, which enabled
aluminum to be used in many applications, including in the steel industry.
Reflect on Your Learning
67. Answers may vary. Sample answer: I do not find the use of an arbitrary reference
electrode challenging. Instead, I find it helpful. It helps scientists to compare different
cells using one standard. Many measured quantities have an arbitrary “zero”, for
example, temperature measured in degrees Celsius or degrees Fahrenheit; time measured
in years CE or BCE; and longitude measured east of west of the Prime Meridian.
68. Answers may vary. Sample answer: Before studying this chapter, I knew commercial
batteries contained some substance that produced electricity by undergoing a chemical
reaction, but I thought when the battery went dead the chemicals inside had all been
released, and were no longer inside the battery. I now understand that the chemicals do
not leave the battery, but they transform from reactants to products. Recharging a battery
reverses the chemical reactions so that the battery once again contains reactants and can
produce energy by undergoing the reaction again.
69. Answers may vary. Students should include examples of items they use in their lives
that involve spontaneous electrochemical reactions, such as battery-powered phones and
corrosion of vehicles; as well as examples of items they use that were created by nonspontaneous electrochemical reactions, such as metal plated items and recharged
batteries.
70. Answers may vary. Students should discuss the importance of making sure that
results are accurate so they do not mislead other scientists, as well as the competitive
nature of science that motivates scientists to want to be the first to announce new
discoveries.
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Chapter 10: Electrochemical Cells
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Research
71. Answers may vary, and should be presented according to question guidelines. Plating
with gold, nickel, zinc, or other metals may be accomplished at home by purchasing kits
designed for this purpose. These kits include most of the materials required for the
procedure such as electrodes, chemicals, wires, and detailed instructions. Students may
research one of these kits and make a plan for electroplating the ornament based on the
included materials and instructions. Safety precautions, disposal methods, and
appropriate attire such as gloves and goggles should also be taken into consideration,
because some materials used in metal-plating, such as cyanide and chromic acid, are
toxic. Some toxic or hazardous chemicals may not be appropriate to use at home under
any circumstances.
72. Answers may vary, and should be presented according to question guidelines. One
type of battery that students may research is the common alkaline battery, used in devices
such as flashlights and remote controls. This type of battery contains a zinc metal anode,
manganese dioxide cathode, and potassium hydroxide as the electrolyte. A cell consists
of a cylinder with the manganese dioxide along the inner surface, separated from the zinc
at the centre. The ions in the electrolyte solution can move freely through the porous
separator. Alkaline batteries are cost-effective, easily available, and provide good
performance. However, the alkaline electrolyte solution is corrosive and prone to leakage.
Alkaline batteries are generally not rechargeable and should be recycled. Facilities for
recycling will vary among municipalities.
73. Answers may vary. Sample answer:
Advantages and Disadvantages of Lithium-ion Batteries
Advantages
Disadvantages
rechargeable
expensive
large cell potential
risk of explosion if overheated
small mass
performance decreases with use and age
variety of shapes and sizes
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Chapter 10: Electrochemical Cells
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74. Answers may vary. Sample answer: Lead storage batteries contain lead and sulfuric
acid, and are classified as hazardous waste; they should be disposed of properly in order
to minimize their environmental impact.
75. Lead storage batteries have been used in vehicles for the past century. These
rechargeable batteries contain lead-based electrodes and sulfuric acid as an electrolyte.
Lithium-ion batteries are frequently used in electric cars. Their electrodes may be
composed of various materials between which lithium ions move. Lead storage batteries
are durable and relatively inexpensive but there are environmental concerns associated
with them because of their lead content. Lithium ion batteries have a larger cell potential,
are relatively small and lightweight, and include environmentally safe components; a
major disadvantage, however, is their high cost.
76. Answers may vary, and should be presented according to question guidelines. A
“cradle to grave” analysis of new batteries involves assessing the entire life cycle of the
batteries and their components to determine environmental consequences. This includes
the environmental impact associated with acquisition of raw materials, manufacturing,
distribution, usage, and disposal of the batteries. Students should evaluate the benefits of
such an analysis and state an opinion about whether it should be necessary to conduct this
type of analysis on new batteries prior to their introduction.
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77. Answers may vary. Sample answer:
Benefits and Consequences of Recycling Aluminum
Benefits
Consequences
costs less than manufacturing from raw
none
materials
lower energy consumption
lower greenhouse gas emissions
reduced landfill
The percentage of aluminum that is recycled can be increased by raising awareness about
common recyclable aluminum products such as beverage cans and by increasing the
availability of recycling programs. Global aluminum recycling rates are between 70 %
(for beverage cans) and 90 % (for construction and transportation uses of aluminum).
78. Answers may vary, and should include at least two “greener” electrolytic reactions.
One example of an industrial process that produces a harmful byproduct is the
cyanidation process used in the recovery of gold from ore:
4 Au(s) + 8 NaCN(aq) + O2(g) + 2 H2O(l) → 4 NaAu(CN) 2(aq) + 4 NaOH(aq)
This redox reaction produces a soluble gold-cyanide complex, which is recovered in a
subsequent precipitation reaction. However, the process solution contains free cyanide
ions and byproducts such as cyanide metal complexes. Accidental spills can reach bodies
of water and pose a hazard to the environment.
A “greener” electrolytic reaction is the thiosulphate leaching of gold. The process also
involves ammonia and copper catalysts, but a simplified overall reaction is given below:
4 Au(s) + 8 S2O32–(aq) + O2(g) + 2 H2O(l) → 4 [Au(S2O3)2]3–(aq) + 4 OH–(aq)
This process does not involve cyanide and is a less-toxic alternative.
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Chapter 10: Electrochemical Cells
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