Exercise 5 We consider a germanium crystal of type P, resistivity 0.01 2. cm at 27 °C. We recall that for such a temperature, the intrinsic concentration is given by the Ea law n₁ = AT³/²exp (- 5ª), with A = 1022. The mobility of the holes is then 2kT 0.17 S.I. Recall that k = 1.38x10-23 S.I. 1. Calculate the hole concentration; 2. Deduce the concentration of free electrons 3. Repeat the calculations of questions a) and b) for a germanium crystal with resistivity 10.0 2. cm.

Exercise 5

 

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Exercise 4 A copper wire of diameter D = 1mm is crossed by an intensity of 2A. knowing that the electron concentration is 8.45x1028 m-3, determine the rate at which the electrons are drawn. It is assumed that the wire is 2.5 m long and that it is subjected to a potential difference of 0.1 V. Then calculate the mobility of the electrons and deduce the conductivity of the wire. Exercise 5 We consider a germanium crystal of type P, resistivity 0.01 2. cm at 27 °C. We recall that for such a temperature, the intrinsic concentration is given by the law n₁ = AT³/² exp(-), with A = 10²2. The mobility of the holes is then 0.17 S.I. Recall that k = 1.38x10-23 S.I. 1. Calculate the hole concentration; 2. Deduce the concentration of free electrons 3. Repeat the calculations of questions a) and b) for a germanium crystal with resistivity 10.0 2. cm. Exercise 6 Evaluate the density of charge carriers in intrinsic silicon at 300 K. We give Eg = 1.12eV, mi = 0.98m, m = 0.19m, min = 0.16m, mhh = 0.49m. Knowing that me = (6) 2/3 (mim²) ¹/3, mi (mi2/2 + m3/2)2/3 and +3/2 3/4 3/4 - (2.5 (³) n₁ = 2K)) 10 Eg 3/2 Т (T)³7² exp(-2KBT) 1019 cm-3. Calculate the concentration of charge carriers at T = 300 K in silicon doped with 1016 arsenic atoms per cm³ if n = 1.45x10¹0 cm-³.