1. ELECTROCHEMISTRY
CHARGE (Q) – A property of matter which causes it to experience the electromagnetic force
COULOMB (C) – The quantity of charge equal to × 1018 electrons
ELECTRIC CURRENT or AMPERAGE (I) – The rate of flow of electric charge
AMPERE (A) – Flow rate of one coulomb of electric charge per second
ELECTROMOTIVE FORCE or POTENTIAL or VOLTAGE (Ɛ) – The potential difference between 2 substances, causing electrons to flow from one to the other
VOLT (V) – One joule of potential energy per coulomb
3D-1 (of 20)

2. Spontaneous oxidation-reduction reaction:
Fe (s) + Cu2+ (aq) → Fe2+ (aq) + Cu (s)
Iron is more reactive than copper,  iron atoms will release their valence electrons to the copper (II) ions
Redox reactions can be written as the sum of 2 half-reactions
Oxidation:
Reduction:
Fe (s) → Fe2+ (aq)
Cu2+ (aq) → Cu (s)
+ 2e-
2e- +
Fe (s) + 2e- + Cu2+ (aq) → Fe2+ (aq) + Cu (s) + 2e-
Fe (s) + Cu2+ (aq) → Fe2+ (aq) + Cu (s)
If the Fe (s) and Cu2+ (aq) are separated, the electron transfer can go through a wire
3D-2 (of 20)

3. ANODE – The electrode where oxidation occurs
CATHODE – The electrode where reduction occurs
0.78 V is called the cell potential, the cell voltage, or the cell emf
3D-3 (of 20)

4. GALVANIC CELL – An electrochemical cell that produces electric current from a chemical reaction
Shorthand notation:
Anode | Anode Solution || Cathode Solution | Cathode
Fe | Fe2+ (1 M) || Cu2+ (1 M) | Cu
3D-4 (of 20)

5. The ΔG of a reaction occurring in a Galvanic cell is related to Ɛ
ΔG = -nFƐ
n = number of moles of electrons transferred in the redox reaction
F = the Faraday constant
the charge of 1 mole of electrons, equal to 96,485 C
Ɛ = electromotive force or voltage
potential difference causing electrons to flow
For Galvanic cells with 1 M concentrations
ΔGº = -nFƐº
J =
(mol)
(C/mol)
(V)
(J/C)
3D-5 (of 20)

6. Calculate ΔGº for the reaction
Fe (s) + Cu2+ (aq) → Fe2+ (aq) + Cu (s) Ɛº = V
INTENSIVE PROPERTY – One that does not depend on the amount of chemical change
ΔGº = -nFƐº
= -(2 mol)(96,485 C/mol)(0.78 V)
= -(2 mol)(96,485 C/mol)(0.78 J/C)
= -150,000 J
ΔG < 0 and Ɛ > 0 means a spontaneous process
The more negative ΔG, the more spontaneous the process
The more positive Ɛ, the more spontaneous the process
3D-6 (of 20)

7. REDUCTION AND OXIDATION POTENTIALS
REDUCTION POTENTIAL (Ɛred) – The electric potential for a reduction half-reaction
OXIDATION POTENTIAL (Ɛox) – The electric potential for an oxidation half-reaction
Ɛºred and Ɛºox are for a standard state half-reactions
The more positive the Ɛred or Ɛox, the more spontaneous the half-reaction
2e- + F2 (g) → 2F- (aq)
Ɛºred = V
2e- + l2 (s) → 2l- (aq)
Ɛºred = V
K (s) → K+ (aq) + e-
Ɛºox = V
Ca (s) → Ca2+ (aq) + 2e-
Ɛºox = V
Cu (s) → Cu2+ (aq) + 2e-
Ɛºox = V
3D-7 (of 20)

8. The potential of an overall redox reaction in a Galvanic cell can be measured with a voltmeter
Fe (s) → Fe2+ (aq) + 2e-
2e- + Cu2+ (aq) → Cu (s)
Ɛºox = V
Ɛºred = V
Ɛºox = V
Ɛºred = V
Fe (s) + Cu2+ (aq) → Fe2+ (aq) + Cu (s)
Ɛº = V
The sum of a reduction potential and an oxidation potential must equal the potential for the overall redox reaction
Unfortunately, the potential of a half-reaction cannot be measured,
so we make one up!
3D-8 (of 20)

9. H2 (g, 1 atm) → 2H+ (aq, 1 M) + 2e-
This standard hydrogen half-reaction is assigned a potential of 0.00 V
All other standard reduction potentials are measured relative to this one
H2 (g) → 2H+ (aq) + 2e-
2e- + Cu2+ (aq) → Cu (s)
Ɛºox = V
Ɛºred = V
H2 (g) + Cu2+ (aq) → 2H+ (aq) + Cu (s)
Ɛº = V
3D-10 (of 20)

10. H2 (g, 1 atm) → 2H+ (aq, 1 M) + 2e-
This standard hydrogen half-reaction is assigned a potential of 0.00 V
All other standard reduction potentials are measured relative to this one
And, Ɛred’s always mean “per one mole of e- change”
3D-11 (of 20)

11. USES FOR STANDARD REDUCTION POTENTIALS
1) Predicting the spontaneity of a reaction
Determine if the following standard state reaction is spontaneous:
3Fe (s) + 2Cr3+ (aq) → 3Fe2+ (aq) + 2Cr (s)
Find the 2 reduction potentials that can be used to make the reaction
2e- + Fe2+ (aq) → Fe (s)
3e- + Cr3+ (aq) → Cr (s)
Ɛºred = V
Ɛºred = V
Add a reduction and oxidation half-reaction to make the desired reaction
3D-12 (of 20)

12. USES FOR STANDARD REDUCTION POTENTIALS
1) Predicting the spontaneity of a reaction
Determine if the following standard state reaction is spontaneous:
3Fe (s) + 2Cr3+ (aq) → 3Fe2+ (aq) + 2Cr (s)
Find the 2 reduction potentials that can be used to make the reaction
Fe (s) → Fe2+ (aq) + 2e-
3e- + Cr3+ (aq) → Cr (s)
Ɛºox = V
Ɛºred = V
Ɛº = V
Ɛº is negative,  the reaction is nonspontaneous
3D-13 (of 20)

13. USES FOR STANDARD REDUCTION POTENTIALS
2) Predicting strong oxidizing and reducing agents
A large, positive reduction potential means the forward reaction is spontaneous (the REACTANT has a strong tendency to be REDUCED)
Best oxidizing agent from the list? F2
A large, negative reduction potential means the reverse reaction is spontaneous (the PRODUCT has a strong tendency to be OXIDIZED)
Best reducing agent from the list? Li
3D-14 (of 20)

14. USES FOR STANDARD REDUCTION POTENTIALS
3) Predicting the potential and spontaneous reaction in a Galvanic cell
3D-15 (of 20)

15. For a Galvanic cell with silver and nickel electrodes in 1 M solutions of Ag+ and Ni2+ respectively, determine the (a) standard cell potential, (b) spontaneous reaction, and (c) anode and cathode
(a) Find the 2 reduction potentials to produce the Galvanic cell
e Ag+ (aq) → Ag (s)
2e- + Ni2+ (aq) → Ni (s)
Ɛºred = V
Ɛºred = V
The largest positive potential is the spontaneous process, and will be the reduction
the other must be reversed, and will be the oxidation
3D-16 (of 20)

16. For a Galvanic cell with silver and nickel electrodes in 1 M solutions of Ag+ and Ni2+ respectively, determine the (a) standard cell potential, (b) spontaneous reaction, and (c) anode and cathode
(a) Find the 2 reduction potentials to produce the Galvanic cell
e Ag+ (aq) → Ag (s)
Ni (s) → Ni2+ (aq) + 2e-
Ɛºred = V
Ɛºox = V
1.03 V
Add the reduction and oxidation potentials to get the cell potential
3D-17 (of 20)

17. For a Galvanic cell with silver and nickel electrodes in 1 M solutions of Ag+ and Ni2+ respectively, determine the (a) standard cell potential, (b) spontaneous reaction, and (c) anode and cathode
(b) Equalize e-s and add the reduction and oxidation half-reactions together
( ) x 2
e Ag+ (aq) → Ag (s)
Ni (s) → Ni2+ (aq) + 2e-
Ɛºred = V
Ɛºox = V
1.03 V
3D-18 (of 20)

18. For a Galvanic cell with silver and nickel electrodes in 1 M solutions of Ag+ and Ni2+ respectively, determine the (a) standard cell potential, (b) spontaneous reaction, and (c) anode and cathode
(b) Equalize e-s and add the reduction and oxidation half-reactions together
2e Ag+ (aq) → 2Ag (s)
Ni (s) → Ni2+ (aq) + 2e-
Ɛºred = V
Ɛºox = V
2Ag+ (aq) + Ni (s) → 2Ag (s) + Ni2+ (aq)
1.03 V
(c)
Nickel half-reaction is the oxidation, ∴ Ni is the anode
Silver half-reaction is the reduction, ∴ Ag is the cathode
3D-19 (of 20)

19. For a Galvanic cell with cadmium and chromium electrodes in 1 M solutions of Cd2+ and Cr3+ respectively, determine the (a) standard cell potential, (b) spontaneous reaction, and (c) anode and cathode
2e- + Cd2+ (aq) → Cd (s)
3e- + Cr3+ (aq) → Cr (s)
Ɛºred = V
Ɛºred = V
3 x ( )
2e- + Cd2+ (aq) → Cd (s)
Cr (s) → Cr3+ (aq) + 3e-
Ɛºred = V
Ɛºox = V
2 x ( )
0.23 V
6e Cd2+ (aq) → 3Cd (s)
2Cr (s) → 2Cr3+ (aq) + 6e-
3Cd2+ (aq) + 3Cr (s) → 3Cd (s) + 2Cr3+ (aq)
Cd2+ is reduced
∴ Cd is the cathode
Cr is oxidized
∴ Cr is the anode
3D-20 (of 20)

21. NONSTANDARD STATE CELLS
For nonstandard cells
ΔG = ΔGº + RT ln Q
because ΔG = -nFƐ and ΔGº = -nFƐº
-nFƐ = -nFƐº + RT ln Q
THE NERNST EQUATION
Ɛ = Ɛº – RT ln Q
____ nF
3E-1 (of 11)

22. Zn (s) | Zn2+ (0.200 M) || Ag+ (0.100 M) | Ag (s)
Calculate the potential for the following cell at 298 K
Zn (s) | Zn2+ (0.200 M) || Ag+ (0.100 M) | Ag (s)
e- + Ag+ (aq) → Ag (s)
2e- + Zn2+ (aq) → Zn (s)
Ɛºred = V
Ɛºred = V
e- + Ag+ (aq) → Ag (s)
Zn (s) → Zn2+ (aq) + 2e-
Ɛºred = V
Ɛºox = V
0.80 V V = V
3E-2 (of 11)

23. Zn (s) | Zn2+ (0.200 M) || Ag+ (0.100 M) | Ag (s)
Calculate the potential for the following cell at 298 K
Zn (s) | Zn2+ (0.200 M) || Ag+ (0.100 M) | Ag (s)
( ) x 2
e- + Ag+ (aq) → Ag (s)
Zn (s) → Zn2+ (aq) + 2e-
Q = [Zn2+]
_________
[Ag+]2
2Ag+ (aq) + Zn (s) → 2Ag (s) + Zn2+ (aq)
Ɛ = Ɛº – RT ln Q
____ nF
= V – (8.314 CV/K)(298 K) ln
___________________________ ________
(2 mol)(96,485 C/mol)
= V – V
= V
3E-3 (of 11)

24. For a nickel-cadmium cell with solutions of 0
For a nickel-cadmium cell with solutions of M nickel (II) sulfate and 0.10 M cadmium sulfate, determine the (a) standard cell potential,
(b) spontaneous reaction, (c) anode and cathode (d) cell potential at 298 K
2e- + Ni2+ (aq) → Ni (s)
2e- + Cd2+ (aq) → Cd (s)
Ɛºred = V
Ɛºred = V
2e- + Ni2+ (aq) → Ni (s)
Cd (s) → Cd2+ (aq) + 2e-
Ɛºred = V
Ɛºox = V
-0.23 V V = V
3E-4 (of 11)

25. For a nickel-cadmium cell with solutions of 0
For a nickel-cadmium cell with solutions of M nickel (II) sulfate and 0.10 M cadmium sulfate, determine the (a) standard cell potential,
(b) spontaneous reaction, (c) anode and cathode (d) cell potential at 298 K
2e- + Ni2+ (aq) → Ni(s)
Cd (s) → Cd2+ (aq) + 2e-
Ni – cathode
Cd – anode
Ni2+ (aq) + Cd (s) → Ni (s) + Cd2+ (aq)
Q = [Cd2+]
________
[Ni2+]
Ɛ = Ɛº – RT ln Q
____ nF
= V – (8.314 CV/K)(298 K) ln
___________________________ __________
(2 mol)(96,485 C/mol)
= V – V
= V
3E-5 (of 11)

26. For a nickel-cadmium cell with solutions of 0
For a nickel-cadmium cell with solutions of M nickel (II) sulfate and 0.10 M cadmium sulfate, determine the (e) the cell potential at 298 K once 90.% of the nickel (II) ions have reacted away
Ni2+ (aq) + Cd (s) → Ni (s) + Cd2+ (aq)
Q = [Cd2+]
_________
[Ni2+]
Initial M’s
Change in M’s
Final M’s
0.10
Ɛ = Ɛº – RT ln Q
____ nF
= V – (8.314 CV/K)(298 K) ln
___________________________ __________
(2 mol)(96,485 C/mol)
= V – V
= V
3E-6 (of 11)

27. For a reaction at equilibrium
ΔG = 0
∴ Ɛ = 0
Ɛ = Ɛº – RT ln Q
____ nF
RT ln Keq = Ɛº
____ nF
0 = Ɛº – RT ln Keq
____ nF
ln Keq = ƐºnF
______ RT
RT ln Keq = Ɛº
____ nF
Keq = eƐºnF/RT
3E-7 (of 11)

28. Fe (s) + I2 (s) → Fe2+ (aq) + 2I- (aq)
Find the equilibrium constant at 298 K for
Fe (s) + I2 (s) → Fe2+ (aq) + 2I- (aq)
2e- + I2 (s) → 2I- (aq)
2e- + Fe2+ (aq) → Fe (s)
Ɛºred = V
Ɛºred = V
2e- + I2 (s) → 2I- (aq)
Fe (s) → Fe2+ (aq) + 2e-
Ɛºred = V
Ɛºox = V
I2 (s) + Fe (s) → 2I- (aq) + Fe2+ (aq)
0.54 V V = V
3E-8 (of 11)

29. Fe (s) + I2 (s) → Fe2+ (aq) + 2I- (aq)
Find the equilibrium constant at 298 K for
Fe (s) + I2 (s) → Fe2+ (aq) + 2I- (aq)
Keq = eƐºnF/RT
= e[(0.98 V)(2 mol)(96,485 C/mol)] / [(8.314 CV/K)(298 K)]
= 1.3 x 1033
3E-9 (of 11)

30. Find the solubility product constant for mercury (I) chloride at 298 K
Hg2Cl2 (s) ⇄ Hg22+ (aq) + 2Cl- (aq)
2e- + Hg2Cl2 (s) → 2Hg (l) + 2Cl- (aq)
2e- + Hg22+ (aq) → 2Hg (l)
Ɛºred = V
Ɛºred = V
2e- + Hg2Cl2 (s) → 2Hg (l) + 2Cl- (aq)
2Hg (l) → Hg22+ (aq) + 2e-
Ɛºred = V
Ɛºox = V
Hg2Cl2 (s) ⇄ Hg22+ (aq) + 2Cl- (aq)
0.33 V – V = V
3E-10 (of 11)

31. Hg2Cl2 (s) ⇄ Hg22+ (aq) + 2Cl- (aq)
Find the solubility product constant for mercury (I) chloride at 298 K
Hg2Cl2 (s) ⇄ Hg22+ (aq) + 2Cl- (aq)
Ksp = eƐºnF/RT
= e[(-0.47 V)(2 mol)(96,485 C/mol)] / [(8.314 CV/K)(298 K)]
= 1.3 x 10-16
3E-11 (of 11)

33. BATTERIES
BATTERY – One or more electrochemical cells that produce electricity from a chemical reaction
3F-1 (of 17)

34. Dry Cell
Graphite rod (cathode)
Paste of MnO2, NH4Cl, and H2O
Zinc casing (anode)
Anode:
Cathode:
Zn (s) → Zn2+ (aq) + 2e-
2e- + 2MnO2 (s) + 8NH4+ (aq) → 2Mn3+ (aq) + 4H2O (l) + 8NH3 (aq)
Potential or Voltage : 1.5 V
Current or Amperage : Depends on battery size
3F-2 (of 17)

35. Dry Cell
Graphite rod (cathode)
Paste of MnO2, NH4Cl, and H2O
Zinc casing (anode)
The acidic content tends to corrode the Zn
Fast usage : NH3 insulates the cathode, reducing the voltage
With rest : Zn2+ migrates to center, forming Zn(NH3)42+ to bind the NH3
3F-2 (of 17)

36. Alkaline Battery
Graphite rod (cathode)
Paste of MnO2, KOH, and H2O
Powdered zinc (anode)
Anode:
Cathode:
Zn (s) + OH- (aq) → ZnO (s) + H2O (l) + 2e-
2e MnO2 (s) + H2O (l) → 2Mn2O3 (s) + 2OH- (aq)
Zn resists corrosion in a basic solution
3F-4 (of 17)

37. Lithium-Ion Battery
Lithium cobalt oxide (anode)
Separator
Graphite (cathode)
Anode:
Cathode:
LiCoO2 (s) → CoO2 (s) + Li+ (org) + e-
e- + Li+ (org) + 6C (s) → LiC6 (s)
Because both products stick to the electrodes, by applying an external source of electricity the reverse reaction will occur, reforming the reactants
This is called RECHARGING
3F-5 (of 17)

38. Lead Storage Battery
Lead (anode)
Lead + lead (IV) oxide (cathode)
4 M sulfuric acid
Anode:
Cathode:
Pb (s) + SO42- (aq) → PbSO4 (s) + 2e-
2e- + 2PbO2 (s) + 4H+ (aq) + SO42- (aq) → PbSO4 (s) + 2H2O (l)
3F-6 (of 17)

39. Lead Storage Battery
Lead (anode)
Lead + lead (IV) oxide (cathode)
4 M sulfuric acid
Potential or Voltage: V x 6 cells = V
_______
cell
Because products stick to the electrodes, this battery is rechargeable
3F-7 (of 17)

40. Hydrogen Fuel Cell
Platinum Catalyst
Polymer Electrolyte Membrane
Anode: Pt catalyst splits hydrogen atoms into hydrogen ions and electrons
Electrolyte: PEM allows hydrogen ions to pass through to the cathode
Cathode: Oxygen and electrons combine with hydrogen ions to make water
3F-8 (of 17)

41. (an element’s oxidation number goes down)
ELECTROLYTIC CELL – An electrochemical cell that uses electricity to produce a chemical reaction
Cathode: Reduction
H(OH) (l) → H2 (g)
(an element’s oxidation number goes down)
H+ → H20
2e- + 2
+ OH- (aq) 2
H2O
+1 -2
Anode: Oxidation
H2O (l) → O2 (g)
(an element’s oxidation number goes up)
O2- → O20 2
+ 4H+ (aq)
+ 4e-
3F-9 (of 17)

42. Cathode: the cation is reduced to its elemental form
e- + M+ → M0
Anode: the anion is oxidized to its elemental form
N- → N0 + e-
Electricity Cathode Anode
through
M+ N-
KF (l)
NaCl (l)
K (s)
Na (s)
F2 (g)
Cl2 (g)
3F-10 (of 17)

43. Electricity Cathode Anode
through
CuBr2 (aq)
HCl (aq)
NaCl (aq)
KF (aq)
AgNO3 (aq)
H2SO4 (aq)
Na2CO3 (aq)
Cu (s)
H2 (g)
Na (s)
Ag (g)
Br2 (l)
Cl2 (g)
F2 (g)
O2 (g)
Ɛºred
H2 (g)
Na+ (aq) + e- → Na (s)
2H2O (l) + 2e- → H2 (g) + 2OH- (aq)
-2.71 V
-0.83 V
Exception 1 – Metals that blow up in water are not reduced, H+ in water is
Alkali metals, Ca2+, Sr2+, Ba2+, Ra2+
Exception 2 – Polyatomic ions are (usually) not oxidized, O2- in water is
3F-11 (of 17)

44. Electrolytic cells are used for (1) producing elements (Na, Cl2, etc.)
(2) purification of metals from ore
(3) electroplating metals (Au, Ag, Pt, etc.)
Anode: Oxidation
Ag (s) → Ag+ (aq) Ag
+ e-
Ag+
Cathode: Reduction
Ag+ (aq) → Ag (s)
e- +
3F-12 (of 17)

45. FARADAY’S LAWS OF ELECTROLYSIS
(1) Passing the same quantity of electricity through a cell always leads to the same amount of chemical change
(2) It takes 96,485 C of electricity to deposit or liberate 1 mole of a substance that gains or loses 1 mole of e-s during the cell reaction
96,485 C = 1 mole e-
= 1 Faraday
3F-13 (of 17)

46. Calculate the mass of copper deposited by a current of 7
Calculate the mass of copper deposited by a current of 7.89 amperes flowing for 1.20 x 103 seconds through a copper (II) nitrate solution.
Cu2+ (aq) + 2e- → Cu (s)
7.89 A
x x 103 s
x 1 C
______
1 As
x F
___________
96,485 C
x 1 mol e-
__________
1 F
x 1 mol Cu
___________
2 mol e-
x g Cu
______________
1 mol Cu
= g Cu
3F-14 (of 17)

47. Calculate the mass of aluminum deposited by a current of 5
Calculate the mass of aluminum deposited by a current of 5.00 amperes flowing for 10.0 minutes through an aluminum nitrate solution.
Al3+ (aq) + 3e- → Al (s)
5.00 A
x min
x s
________
1 min
x 1 C
______
1 As
x F
___________
96,485 C
x 1 mol e-
__________
1 F
x 1 mol Al
___________
3 mol e-
x g Al
_____________
1 mol Al
= g Al
3F-15 (of 17)

48. Calculate the current needed to plate 0
Calculate the current needed to plate grams of zinc onto an electrode in 60.0 seconds from a zinc acetate solution.
Zn2+ (aq) + 2e- → Zn (s)
0.150 g Zn
x mol Zn
_____________
65.38 g Zn
x 2 mol e-
___________
1 mol Zn
x F
__________
1 mol e-
x 96,485 C
___________
1 F
x 1 As
______
1 C x
________
60.0 s
= A
3F-16 (of 17)

49. Calculate the time, in minutes, needed to deposit 0
Calculate the time, in minutes, needed to deposit grams of chromium from a chromium (III) nitrate solution with a current of 10.0 amperes.
Cr3+ (aq) + 3e- → Cr (s)
0.400 g Cr
x mol Cr
_____________
52.00 g Cr
x 3 mol e-
___________
1 mol Cr
x F
__________
1 mol e-
x 96,485 C
___________
1 F
x 1 As
______
1 C x
________
10.0 A
x 1 min
_______
60 s
= min
3F-17 (of 17)

50. REVIEW FOR TEST 3
Entropy
Predict relative absolute entropies values
Predict entropy changes for chemical reactions
1st Law of Thermodynamics
2nd Law of Thermodynamics
3rd Law of Thermodynamics
Free Energy

51. REVIEW FOR TEST 3
For ΔHº, ΔSº, ΔGº
Meaning of each
Calculate each from tables
Calculate from ΔGº = ΔHº - TΔSº
Contributions of ΔH and ΔS to spontaneity
Calculate ΔG from ΔG = ΔGº + RTlnQ
Relationships between ΔG, ΔGº, and Keq
Keq from ΔGº
ΔGº from Keq
ΔHº and ΔSº from a van’t Hoff Plot using Excel

52. REVIEW FOR TEST 3
Charge in coulombs
Electric Current in amperes
Electric potential in volts
Galvanic Cell
Anode
Cathode
Reduction Potentials
Predicting strong oxidizing and reducing agents from reduction potentials

53. REVIEW FOR TEST 3
For a Galvanic Cell, determine
Standard Cell Potential from Standard Reduction Potentials
Half-Reaction at the Anode and the Cathode
Spontaneous Reaction
Line Notation
Calculate Ɛ from Ɛ = Ɛº - (RT/nF)lnQ
Relationship between Ɛ, Ɛº, and Keq
Keq from Ɛº
Ɛº from Keq
Relationship between ΔGº, Ɛº and Keq

54. REVIEW FOR TEST 3
Electrolytic Cell
Electrolysis products
Faraday Law calculations
Corrosion
Experiments 5, 13-18
Qualitative Analysis of Groups I, II, and III Cations
Ion Colors
Complex Ions
Reading