Description
. The bandgap energy in a semiconductor is usually a slight function of temperature. In some cases, the bandgap energy versus temperature can be modeled by
πΌπ2
πΈπ =πΈπ(0)β
π½+π
where πΈπ(0)Β is the value of the bandgap energy at π=0πΎ. For silicon, the parameter values are πΈπ(0)=1.170ππ, πΌ=4.73Γ10β4ππ/πΎ, and π½=636πΎ. Plot πΈπ versus T over the range 0β€πβ€600πΎ. In particular, note the value at π=300πΎ.Β 2. The E versus k diagram for a particular allowed energy band is shown in Figure P3.15. Determine (a) the sign of the effective mass and (b) the direction of velocity for a particle at each of the four positions shown.
- The figure below shows the parabolic E versus k relationship in the conduction band for an electron in two particular semiconductor materials, A and B. determine the effective mass (in units of the free electron mass) of the two electrons.
- (a) The forbidden bandgap energy in GaAs is 1.42 eV. (i) Determine the minimum frequency of an incident photon that can interact with a valence electron and elevate the electron to the conduction band. (ii) What is the corresponding wavelength? (b) Repeat part (a) for silicon with a bandgap energy of 1.12 eV.
