EcEEFEvEnergy banddiagramEgElectronDensityof statesEA D.(E)D₂(E)N(E)EFEOccupancyprobabilityII0.5f(E)1ECarrierdistributionsElectronsHolesO HoleFIGURE 1-20 Schematic band diagram, density of states, Fermi-Dirac distribution,and carrier distributions versus energy. The carrier distributions in the conduction and valence bands were noted to peak atenergies close to the band edges. (Refer to carrier distribution in Fig. 1-20.) UsingBoltzmann approximation, show that the energy at which the carrier distribution peaksis Ec+kT/2 and E-kT/2 for the conduction and valence bands, respectively.

carrier distributions for the valence and conduction electron is given in the figure.For n-type…

Answered: The carrier distributions in the…

Similar questions

Ex 4.11 Consider silicon at T = 300 K. Calculate the thermal-equilibrium electron and hole concentrations for impurity concentrations of (a) Na = 4 X 1016 cm, Na = 8 X 1015 cm-3 and (b) Na = Na = 3 X 1015 cm-3.
find the value
The half-wave rectifier in Figure 2–19 has a 250-μF filter capacitor and a 1.5-kOhm load. The ac source is 120 V rms with frequency 60 Hz. The voltage drop across the silicon diode is 0.7V. Assuming light loading, find (d) plot vin(t), vR(t) (output without the filter cap) and vL(t) (output with the filter cap) all on the same graph
(2.9) The magnetic susceptibility of platinum is 2.61×10−4, The density of platinum is 21450 kg m-3 and its relative atomic mass is given by 195.09 g mol-¹. Calculate its molar susceptibility (in m³ mol-¹) and its mass susceptibility (in m³ kg-1). Using Appendix A, translate these results into cgs units to find the molar susceptibility in emu mol-¹ and the mass susceptibility in emu g-¹. To understand why the magnetic susceptibility of platinum, a metal, is temperature independent (in contrast with Curie's law), see chapter 7.
Answer the following question step-wisewise showing clearly all steps
Estimate kBT at room temperature, and convert this energy into electronvolts (eV). Using this result, answer the following: (a) Would you expect hydrogen atoms to be ionized at room temperature? (The binding energy of an electron in a hydrogen atom is 13.6 eV.) (b) Would you expect the rotational energy levels of diatomic molecules to be excited at room temperature? (It costs about 10−4 eV to promote such a system to an excited rotational energy level.)