5 Must Know Facts For Your Next Test

1. In galvanic cells, the cathode is positively charged because it attracts electrons from the anode, leading to reduction.
2. In electrolytic cells, the cathode is negatively charged, as it is connected to the positive terminal of an external power source, forcing reduction to occur.
3. The specific reactions at the cathode vary depending on the type of electrochemical cell, influencing overall efficiency and performance.
4. In fuel cells, hydrogen typically acts as a fuel and is oxidized at the anode while oxygen is reduced at the cathode, producing water and electricity.
5. Understanding the behavior of the cathode is essential for improving battery technology and developing more efficient fuel cells.

Review Questions

• How does the charge of the cathode differ between galvanic and electrolytic cells, and why is this significant?
  • In galvanic cells, the cathode is positively charged because it attracts electrons from the anode as reduction occurs. Conversely, in electrolytic cells, the cathode is negatively charged since it is connected to a power source that drives electron flow toward it. This difference in charge affects how reactions occur at the electrodes and has implications for energy efficiency in different types of electrochemical systems.
• Discuss the role of the cathode in a fuel cell and how it contributes to the overall reaction.
  • In a fuel cell, the cathode plays a vital role by facilitating the reduction of oxygen gas. When hydrogen is oxidized at the anode, electrons are released and travel to the cathode. Here, they combine with oxygen molecules and protons that have moved through an electrolyte, forming water as a product. This process generates electricity efficiently and illustrates how critical the cathode's function is for energy conversion in fuel cells.
• Evaluate how advancements in materials used for cathodes can enhance battery performance and longevity.
  • Advancements in materials for cathodes can significantly improve battery performance by increasing energy density, charging speed, and cycle life. For example, using materials like lithium iron phosphate or graphene can enhance conductivity and stability during redox reactions. These innovations lead to batteries that last longer and operate more efficiently, impacting everything from consumer electronics to electric vehicles. Thus, exploring new materials for cathodes is crucial for meeting future energy demands.

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