13.1.2 Exploring p-n junctions

Cards (87)

  • A p-type semiconductor is doped with trivalent impurities.
  • What type of charge carriers are dominant in an n-type semiconductor?
    Free electrons
  • What is the main charge carrier in an n-type semiconductor?
    Electrons
  • What is the depletion region in a p-n junction depleted of?
    Free charge carriers
  • The built-in potential at a p-n junction establishes an equilibrium state.
  • What type of impurities are used to create electron holes in a p-type semiconductor?
    Trivalent
  • Match the property with the correct semiconductor type:
    Trivalent dopant ↔️ p-type
    Pentavalent dopant ↔️ n-type
  • The depletion region in a p-n junction forms a built-in potential.
  • When p-type and n-type semiconductors are brought together, the free electrons in the n-type region diffuse into the p-type region, and the electron holes in the p-type region diffuse into the n-type region. This process is called diffusion
  • What is the built-in potential in a p-n junction?
    Electric potential across depletion region
  • A p-type semiconductor has excess free electrons.
    False
  • Steps in the formation of a p-n junction
    1️⃣ Diffusion of free electrons and holes
    2️⃣ Formation of the depletion region
    3️⃣ Creation of built-in potential
  • The p-n junction is formed when a p-type semiconductor is brought into contact with an n-type
  • The diffusion current in a p-n junction is caused by a concentration gradient
  • Steps in the formation of the depletion region at a p-n junction
    1️⃣ Free electrons in the n-type region diffuse into the p-type region
    2️⃣ Electron holes in the p-type region diffuse into the n-type region
    3️⃣ Electrons and holes recombine, leaving behind immobile ions
    4️⃣ A built-in potential forms across the depletion region
  • What is the role of the built-in potential in a p-n junction?
    Prevents further diffusion
  • Which current is dominant under forward bias in a p-n junction?
    Diffusion current
  • Under forward bias, the depletion region width decreases.

    True
  • Under reverse bias, the built-in potential at a p-n junction is increased
  • Under reverse bias, the overall current flow is dominated by the drift current.
  • A p-type semiconductor has electron holes as its primary charge carriers.
  • In the formation of a p-n junction, free electrons in the n-type region diffuse into the p-type region.
  • The built-in potential acts as a barrier to further diffusion of charge carriers.
    True
  • The depletion region is the area at the p-n junction where there are no free charge carriers
  • Match the current type with its cause:
    Diffusion Current ↔️ Concentration gradient
    Drift Current ↔️ Electric field
  • The built-in potential acts as a barrier to further diffusion of charge carriers.
    True
  • Under forward bias, the drift current is minimal because it is not supported by the applied voltage.

    True
  • Under forward bias, the current flow across the junction is increased
  • Under reverse bias, the depletion region widens and the built-in potential increases.
  • The I-V characteristic of a p-n junction shows a low resistance under forward bias and a high resistance under reverse bias.
  • What type of charge carriers are dominant in a p-type semiconductor?
    Electron holes
  • A p-type semiconductor uses trivalent impurities like Boron, while an n-type semiconductor uses pentavalent impurities like Phosphorus.

    True
  • Steps in the formation of a p-n junction
    1️⃣ Diffusion of charge carriers
    2️⃣ Recombination of charge carriers
    3️⃣ Formation of the depletion region
    4️⃣ Drift current opposes diffusion
    5️⃣ Equilibrium state is established
  • Match the type of current with its cause and direction:
    Diffusion Current ↔️ Concentration gradient, higher to lower concentration
    Drift Current ↔️ Electric field, opposite to field direction
  • What are two common semiconductor devices that rely on the p-n junction?
    Diodes and transistors
  • N-type semiconductors are doped with pentavalent impurities to produce excess free electrons.
  • Holes are the main charge carriers in p-type semiconductors, while electrons are the main charge carriers in n-type semiconductors.
    True
  • Steps in the formation of the depletion region
    1️⃣ Diffusion of free electrons and holes
    2️⃣ Recombination of charge carriers
    3️⃣ Depletion region forms with no free carriers
    4️⃣ Built-in potential establishes equilibrium
  • Steps in the formation of the depletion region
    1️⃣ Diffusion of electrons and holes
    2️⃣ Recombination of charge carriers
    3️⃣ Creation of immobile charged ions
    4️⃣ Formation of built-in potential
  • The built-in potential is determined by the doping concentrations in the p-type and n-type regions