5 Must Know Facts For Your Next Test

1. Intrinsic semiconductors have an equal number of electrons and holes at thermal equilibrium, resulting in zero net charge carrier concentration.
2. The electrical conductivity of intrinsic semiconductors increases with temperature due to the generation of electron-hole pairs from thermal excitation.
3. Silicon is the most commonly used intrinsic semiconductor due to its favorable electrical properties and abundance in nature.
4. At absolute zero temperature, intrinsic semiconductors behave as insulators because there are no available charge carriers to conduct electricity.
5. The behavior of intrinsic semiconductors is critical for understanding device operation in electronics, especially in diodes and transistors.

Review Questions

• How does temperature affect the conductivity of intrinsic semiconductors?
  • Temperature plays a significant role in the conductivity of intrinsic semiconductors. As the temperature increases, more thermal energy is available to excite electrons from the valence band into the conduction band, creating electron-hole pairs. This increase in charge carriers leads to enhanced conductivity. At lower temperatures, the number of charge carriers is minimal, causing these materials to act more like insulators.
• Compare intrinsic semiconductors with extrinsic semiconductors in terms of their electrical properties and applications.
  • Intrinsic semiconductors are pure materials with electrical properties determined solely by their structure and temperature, while extrinsic semiconductors have been doped with impurities to introduce additional charge carriers, enhancing their conductivity. Extrinsic semiconductors can be n-type or p-type depending on whether they have excess electrons or holes. While intrinsic semiconductors are mainly used for understanding fundamental concepts, extrinsic semiconductors are widely used in practical applications like transistors and diodes due to their improved conductivity.
• Evaluate the importance of intrinsic semiconductors in the context of semiconductor technology advancements.
  • Intrinsic semiconductors serve as the foundation for all semiconductor technology advancements, providing crucial insights into the behavior of electronic materials. By studying intrinsic properties like band gap and charge carrier dynamics, researchers can develop new materials and improve existing technologies. Understanding these fundamental aspects allows for innovations in high-performance devices, energy-efficient electronics, and future advancements in quantum computing and optoelectronics. Their role is vital in bridging theoretical concepts with practical applications in modern technology.

© 2024 Fiveable Inc. All rights reserved.

AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.