Semiconductor Physics: verschil tussen versies

Informatie over het vak

Het vak wordt onderwezen in de eerste trimester door prof. V. Afanasiev. Het examen is gesloten boek.

Examenvragen

12 januari 2022 (Version 1)

Question 1

• Describe the physical principle of Deep Level Transient Spectroscopy (DLTS). What physical information can be obtained in this way?

Question 2

• Describe the temperature-induced changes of barrier height at the interfaces of a metal with n- and p-type semiconductors. What effect will it have on the current-voltage and capacitance-voltage characteristics?

-> barrier height refers to both phi_ms as to psi_s, thus to the barrier height and to the surface potential/band bending

Question 3

• What physical mechanisms determine the temperature dependence of semiconductor optical absorption spectra?

27 januari 2022 (Versie 1)

Question 1

• Explain why the binding energies of donor/acceptor levels are so much smaller than the bandgap energy. How can we use the hydrogen model explain this and what are the differences?

Question 2

• Consider a PN-junction in equilibrium. At V=0, draw and explain the curves of carrier concentration, charge density, electric potential and electric field.
• Do the same for forward bias.

Question 3

• Explain the exciton optical absorption, the influence of temperature on the spectrum and the physical mechanisms behind this.

27 januari 2022 (Versie 2)

Question 1

• Describe the physical principle of Deep Level Transient Spectroscopy (DLTS). What physical information can be obtained in this way?

Question 2

• Describe the temperature-induced changes of barrier height at the interfaces of a metal with n- and p-type semiconductors. What effect will it have on the current-voltage and capacitance-voltage characteristics?

Question 3

• What physical mechanisms determine the temperature dependence of semiconductor optical absorption spectra?

12 januari 2021 (Versie 1)

Question 1

• Explain why the binding energies of donor/acceptor levels are so much smaller than the bandgap energy. How can we use the hydrogen model explain this and what are the differences?

Question 2

• Consider a PN-junction in equilibrium. At V=0, draw and explain the curves of carrier concentration, charge density, electric potential and electric field.
• Do the same for forward bias.

Question 3

• Explain the exciton optical absorption, the influence of temperature on the spectrum and the physical mechanisms behind this.

12 januari 2021 (Versie 2)

Question 2

• Consider a PN-junction in equilibrium. At V=0, draw and explain the curves of carrier concentration, charge density, electric potential and electric field.
• Do the same for reverse bias.

16 januari 2020

Question 1

• What properties of a semiconductor affect the reverse current of a p-n junction as opposed to the Schottky diode (metal-semiconductor contact)?

Question 2

• What is the physical origin of the difference between the spectral distributions of optical absorption and luminescence in direct-gap and indirect-gap semiconductors?

Question 3

• Describe the effect of acceptor impurity concentration on the capacitance-voltage characteristics of metal/semiconductor and metal/oxide/semiconductor capacitors.

Other exam questions

• Discuss the effective mass concept within the semi-classical model used for describing electrons (charge carriers) within condensed matter.
  • Explain in more detail the meaning of this for a pure parabolic band.
  • What parameters determine the effective mass within the k.p method for a non-degenerate band? Discuss limitations of the effective mass approximation.
• Derive the Einstein formula for electrons describing the relationship between the diffusion constant and the mobility of an electron in a semiconductor. For help: Consider a p-n junction with nc(x) = N(T)exp(-[Ec-e*phi(x)-mu]/kT).
• A free-standing GaAs film of 10 ?m thickness absorbs 50 % of an incident monochromatic light bundle with photon energy hv = 1.65 eV and power density 10 W/cm². Calculate the absorption coefficient.
  • If we assume a carrier generation efficiency of 1 electron-hole pair/photon, at what depth in the film will the generation rate be reduced to 20 % of its value at the surface and calculate the generation rate at this depth. 1 Joule = 6.24x10^18 eV.