Unit 7: Electrochemistry

Electrochemistry 07

Electrochemistry is the branch of chemistry that studies the relationship between electrical energy and chemical reactions. This unit explores the principles of electrochemical cells, including both galvanic (voltaic) and electrolytic cells. It covers topics such as redox reactions, electrochemical potential, and the application of electrochemistry in various technologies and industries.

  • Electrochemical Cells: Understanding the components and operation of galvanic (voltaic) cells and electrolytic cells.
  • Redox Reactions: Examining oxidation-reduction reactions and their role in electrochemical processes.
  • Electrode Potentials: Studying standard electrode potentials and how they relate to the spontaneity of reactions.
  • Nernst Equation: Applying the Nernst equation to calculate cell potentials under non-standard conditions.
  • Applications of Electrochemistry: Exploring real-world applications, such as batteries, electroplating, and corrosion prevention.
  • Understanding Energy Conversion: Provides insights into how chemical energy is converted into electrical energy and vice versa.
  • Practical Applications: Enhances knowledge relevant to technologies like batteries, fuel cells, and electroplating.
  • Scientific Insight: Builds a foundation for advanced studies in physical chemistry, materials science, and engineering.

This unit is essential for students to grasp the fundamental concepts of electrochemistry, its applications, and its impact on modern technology. Mastery of these concepts is crucial for understanding various electrochemical processes and their practical uses.

a. Electrolytic cell
b. Galvanic cell
c. Nelson’s cell
d. Downs cell

b. Galvanic cell

a. Redox reaction
b. Acid-base reaction
c. Neutralization
d. Decomposition

a. Redox reaction

a. Downs cell
b. Galvanic cell
c. Nelson’s cell
d. Both a and c

b. Galvanic cell

a. +2
b. +6
c. +7
d. +14

b. +6

a. Sugar solution
b. Sulphuric acid solution
c. Lime solution
d. Sodium chloride solution

a. Sugar solution

a. Chemical decay
b. Rusting of iron
c. Rusting of aluminium
d. Rusting of tin

b. Rusting of iron

b. H2

d. Hydrogen behaves as oxidizing agent

a. Fe2O3.nH2O
b. Fe2O3
c. Fe(OH)3.nH2O
d. Fe(OH)3

a. Fe2O3.nH2O

a. Zn
b. H+
c. Cl
d. H2

b. H+