OUTLINE
21-1 Electrical Conduction
21-2 ElectrodesElectrolytic Cells
21-3 The Electrolysis of Molten
Sodium Chloride (the Downs
Cell)
21-4 The Electrolysis of Aqueous
Sodium Chloride
21-5 The Electrolysis of Aqueous
Sodium Sulfate
21-6 Faraday’s Law of Electrolysis
21-7 Commercial Applications of
Electrolytic CellsVoltaic or Galvanic Cells
21-8 The Construction of Simple
Voltaic Cells
21-9 The Zinc–Copper Cell
21-10 The Copper–Silver CellStandard Electrode Potentials
21-11 The Standard Hydrogen
Electrode
21-12 The Zinc–SHE Cell
21-13 The Copper–SHE Cell21-14 Standard Electrode Potentials
21-15 Uses of Standard Electrode
Potentials
21-16 Standard Electrode Potentials
for Other Half-Reactions
21-17 Corrosion
21-18 Corrosion ProtectionEffect of Concentrations (or Partial
Pressures) on Electrode Potentials
21-19 The Nernst Equation
21-20 Using Electrochemical Cells
to Determine Concentrations
21-21 The Relationship of E^0 cellto
G^0 and KPrimary Voltaic Cells
21-22 Dry CellsSecondary Voltaic Cells
21-23 The Lead Storage Battery
21-24 The Nickel–Cadmium
(Nicad) Cell
21-25 The Hydrogen–Oxygen Fuel
CellOBJECTIVES
After you have studied this chapter, you should be able to- Use the terminology of electrochemistry (terms such as “cell,” “electrode,” “cathode,”
“anode”) - Describe the differences between electrolytic cells and voltaic (galvanic) cells
- Recognize oxidation and reduction half-reactions, and know at which electrode each
occurs - Write half-reactions and overall cell reactions for electrolysis processes
- Use Faraday’s Law of Electrolysis to calculate amounts of products formed, amounts of
current passed, time elapsed, and oxidation state - Describe the refining and plating of metals by electrolytic methods
- Describe the construction of simple voltaic cells from half-cells and a salt bridge, and
understand the function of each component - Write half-reactions and overall cell reactions for voltaic cells
Corrosion is an undesirable
electrochemical reaction with very
serious economic consequences. Rust
is formed when iron is oxidized in
the presence of water.