key term - Electrolytic Cell

5 Must Know Facts For Your Next Test

1. In an electrolytic cell, the external power source supplies the energy needed to drive the non-spontaneous reaction.
2. The reactions in an electrolytic cell occur at the electrodes: oxidation at the anode and reduction at the cathode.
3. Electrolytic cells are commonly used in processes like electroplating, where a metal layer is deposited onto a surface.
4. Faraday's laws of electrolysis relate the amount of substance transformed at each electrode to the total electric charge passed through the cell.
5. An electrolytic cell can operate with various types of electrolytes, including molten salts and aqueous solutions.

Review Questions

• How does an electrolytic cell differ from a galvanic cell in terms of energy flow and reaction spontaneity?
  • An electrolytic cell differs from a galvanic cell primarily in that it requires an external power source to drive a non-spontaneous reaction, meaning it consumes electrical energy. In contrast, a galvanic cell generates electrical energy from spontaneous reactions. While galvanic cells produce current as a result of chemical changes, electrolytic cells use current to induce chemical changes, making their operation fundamentally opposite.
• Discuss the role of the anode and cathode in an electrolytic cell and how they relate to oxidation and reduction.
  • In an electrolytic cell, the anode is the site of oxidation, where electrons are released from a substance. Positive ions migrate toward this electrode to gain electrons, while at the cathode, reduction occurs as electrons are supplied to negative ions. This complementary relationship ensures that as one half-reaction (oxidation) takes place at the anode, the other half-reaction (reduction) simultaneously occurs at the cathode, allowing for continuous flow of current.
• Evaluate the importance of Faraday's laws of electrolysis in understanding the efficiency and applications of electrolytic cells.
  • Faraday's laws of electrolysis provide a quantitative basis for predicting how much material will be deposited or consumed during electrolysis based on the amount of electric charge passed through an electrolytic cell. This understanding is crucial for optimizing processes such as electroplating and industrial chemical production, where efficiency and precision are paramount. By applying these laws, chemists can design systems that maximize yield while minimizing energy consumption, enhancing both economic viability and sustainability in various applications.