oxidation

Question 1

When does metal-metal displacement occur

Answer 1

If a solid metal is below the metal ion, then it will displace the metal ion into its solid metal form

Question 2

When does metal-hydrogen displacement occur

Answer 2

If a solid metal is below the hydrogen ion, then it will displace the hydrogen ion into hydrogen gas

Question 3

When does halogen-hallide displacement occur

Answer 3

If a halide ion is below the halogen, then it will displace the halogen

Question 4

What is corrosion

Answer 4

The oxidation of a metal in the presence of air

Question 5

Define an electrode

Answer 5

electrical conductors on which electron transfer occurs at the surface

Question 6

Anode definition

Answer 6

electrode where oxidation occurs

Question 7

What is the anode denoted as for galvanic and electrolytic cells

Answer 7

denoted negative in galvanic cells and positive in electrolytic cells

Question 8

What is the cathode

Answer 8

electrode where reduction occurs

Question 9

What is the cathode denoted as for galvanic and electrolytic cells

Answer 9

denoted positive in galvanic cells and negative in electrolytic cells

Question 10

What is the electrolyte for galvanic cells

Answer 10

solution which contains ions that conduct charge

Question 11

What is the electrolyte for electroyltic cells

Answer 11

molten salt or aqueous solution in which electrodes are immersed
- Allows anions to be attracted to the anode, cations attracted to the cathode

Question 12

Definition of a salt bridge and 3 purposes of it

Answer 12

• contains a non-reactive electrolyte solution
  
  • Maintains electrical neutrality
  • Allows anions to flow from the salt bridge to the anode and cations to flow from the salt bridge to the cathode
  • Completes the electrical circuit

Question 13

External circuit definition

Answer 13

A conductive path allowing electron flow to occur between cells

Question 14

Where do electrons go

Answer 14

Through the power supply to the cathode, being drawn from the anode

Question 15

What electrode is used for solid metal and metal ion cells

Answer 15

metal electrode is used

Question 16

What electrode is used for metal ions indifferent oxidation states

Answer 16

inert electrode used

Question 17

What electrode is used for dissolved non-metal and its ions

Answer 17

inert electrode used

Question 18

What electrode is used gaseous non-metal and its ions

Answer 18

inert electrode used

Question 19

What 2 factors does corrosion of ion require

Answer 19

oxygen + water

Question 20

What does water do in corrosion of water

Answer 20

Water acts as an electrolyte and salt bridge

Question 21

Oxidation and Reduction equations for Corrosion of iron in a normal medium

Answer 21

• Oxidation: Fe(s) ⟶ Fe2+ + 2e-
• Reduction: O₂ + 2H₂O + 4e- ⟶ 4OH-

Question 22

Precipitation reaction for Corrosion of iron in a normal medium

Answer 22

Fe2+ + 2OH- ⟶ Fe(OH)₂

Question 23

Further Oxidation reaction for Corrosion of iron in a normal medium

Answer 23

Fe(OH)₂ + OH- ⟶ Fe(OH)₃ + e-

Question 24

Overall Equation for Corrosion of iron in a normal medium

Answer 24

4Fe + 3O₂ + 2xH₂O ⟶ 2Fe₂O₃.xH₂O

Question 25

Oxidation and Reduction equations for Corrosion of iron in an acidic medium

Answer 25

• Oxidation: Fe(s) ⟶ Fe2+ + 2e-
• Reduction: O₂ + 4H+ + 4e- ⟶ 2H₂O (data sheet)

Question 26

5 Factors affecting Process of Rusting

Answer 26

• Presence of oxygen: this is the oxidising agent - the greater the concentration of oxygen, the greater the rate of corrosion
• Presence of water: increases the flow of ions between anodic and cathodic sites which increases the rate of corrosion
• Presence of electrolytes: improves the efficiency of water as the salt bridge and increases the rate of corrosion
• pH: the lower the pH, the greater the rate of corrosion as the reduction potential of water increases (i.e. its reduction becomes more favourable)
• Presence of less or more reactive: if iron is in contact with a less reactive

Question 27

3 Factors which can prevent rusting

Answer 27

• Inert, non-metallic coating - prevents contact with oxygen and water i.e. painting, plastic, oil
• Inert, metallic coating - prevents contact with oxygen and water i.e. Cu, Sn, Pb
• Galvanising - coating with more reactive metal, such as zinc - The zinc oxidises more readily and forms a protective layer over the iron
  Cathodic protection using a sacrificial anode
  Cathodic Protection using a DC current

Question 28

Explain Cathodic Protection using a sacrifical anode

Answer 28

• a more reactive metal is placed in contact with the iron
  
  • The more reactive metal oxidises and must be replaced periodically
  • The iron now becomes the site for reduction and so O₂ is reduced at this site
  • A very damp or wet environment is needed to act as a salt bridge

Question 29

Explain Cathodic Protection using a DC current

Answer 29

• the iron is connected to the negative terminal of a low voltage DC current
  
  • The excess of electrons prevents oxidation
  • The positive terminal of the power supply is attached to a piece of scrap metal or an inert material (Platinum) which causes the oxidation of H₂O, thus is oxidised over time
  • A very damp or wet environment is needed to act as a salt bridge

Question 30

In what scenario can inert, metallic coating be problematic

Answer 30

if the metallic barrier is damaged as it makes the point of contact with iron more anodic so iron will corrode faster

Question 31

Explain Downs Cell and anode + cathode reactions

Answer 31

• Process of making sodium commercially available through the electrolysis of molten sodium chloride
  
  • Anode: Oxidation of Chlorine gas
  • Cathode: Reduction of Sodium

Question 32

Explain Electroplating and anode + cathode reactions

Answer 32

• The process of electrolysing in order to place a thin film of metal on an object
  
  • Anode: Metal to be used as coating
  • Cathode: The object to be coated

Question 33

Explain Electrorefining and anode + cathode reactions

Answer 33

• Involves purifying a metal where the impure metal anode is itself oxidised
  
  • Anode: Impure metal is oxidised where other metals fall to the bottom as anode slime
  • Cathode: Pure metal

Question 34

Why cant other metals be reduced in electrorefining

Answer 34

Other metals cannot be reduced as voltage is carefully controlled

Question 35

Explain Primary Cells and anode + cathode reactions

Answer 35

• Non-rechargeable cells typically used as disposable batteries
  
  • Anode: Oxidation of zinc
  • Cathode: 2MnO₂ + 2NH₄ + 2e- —> Mn₂O₃ + 2NH₃ + H₂O

Question 36

2 reasons Why can’t primary cell battery be recharged

Answer 36

• The Mn₂O₃ does not revert back to MnO₂ and instead produces MnOOH
• Eventually ammonium chloride produces an acidic environment that corrodes the zinc casing

Question 37

What is a secondary cell

Answer 37

Rechargeable cells typically used as batteries

Question 38

Normal Use of a Secondary Cell equations (Anode/Cathode)

Answer 38

• Anode: flip bottom lead equation
• Cathode: Normal top lead equation

Question 39

Rechargeable Use of a Secondary Cell equations (Anode/Cathode)

Answer 39

• Anode: flip top lead equation
• Cathode: bottom lead equation

Question 40

Define Fuel Cells

Answer 40

Cells which do not store the oxidising or reducing agent and are more “environmentally friendly” in terms of energy production

Question 41

3 Examples of Galvanic and Electrolytic Cells

Answer 41

Galvanic Cell

Examples

• Dry cell (Primary Cell)
• Lead-acid accumulator (Secondary Cell)
• Fuel cells

Electrolytic Cells

Examples

• Electrorefining cells
• Electroplating cells
• Downs Cell

Question 42

3 Similarities between Galvanic and Electrolytic Cells

Answer 42

• Oxidation occurs at the anode/reduction occurs at the cathode
• Cations move towards the cathode/anions move towards the anode
• Both have an External circuit in through which current flows
• Electrolyte for transfer of ions

Question 43

3 Differences Between Galvanic + Electrolytic Cells

Answer 43

Galvanic cell reactions are spontaneous; Electrolytic cell reactions are not spontaneous

Galvanic cells generate a voltage/electric current; Electrolytic cells require an external voltage/electric current

Galvanic cells convert chemical energy to electrical energy; Electrolytic cells convert electrical energy to chemical energy

Charge of the anode is designated as negative; Charge on the anode is designated as positive