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material constant values are not given so I choose suitable values
for band gap intrinsic concentration and Nv the values may vary a
little bit due to that the final have some variations
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6. Consider a germanium semiconductor at T = 300 K. Calculate the thermal equilibrium concentrations of n, and p. for (a) N. = 10 cm", N. = 0, and (b) N. = 5 x 10 cm), N. = 0.
6. Consider a germanium semiconductor at T = 300 K. Calculate the thermal equilibrium concentrations of n, and p. for (a) N. = 10 cm?, N. = 0, and (b) N. = 5 x 10 cm?, N. = 0.
1. Consider a p*n silicon diode at T-300 K with doping concentrations of N 10 cin and N-101 cm-3. The minority carier hole diffusion coefficient is D 12 cm2/s and the minority carrier hole lifetime is po 10-7 s. The cross sectional area is A 10- cm2. Calculate the reverse saturation current and the diode current at a forward-bias voltage of 0.50v A germanium p* n diode at T-300 K has the following parameters: Na 108 cm-3 N,--1016 cm", ,...
Consider a bar of p-type silicon that is uniformly doped to a value of N, 2 x 10 cm at T- 300 K. The applied electric field is zero. A light source is incident on the end of the semiconductor as shown in Figure P6.19. The steady-state concentration of excess carriers generated at-O is op(0) on(0) 2 x 10 cm-. Assume the following Light p type pa .-1200 cm 2 /V-s, μ,-400 cm2 /V-s. To = 10-6 s, and T.-SX...
P4. a. Consider Si doped with P at 2x10^16 cm^-3. determine the carrier concentrations ni, p, and n at T = 300 K. b. Consider a semiconductor with ni = 2.4x10^13cm-3 that is doped such that ND=5x10^13cm^-3. Determine the carrier concentrations n and p. c. Consider a compensation Ge semiconductor with ni = 2.4x10^13 cm^-3 doped at concentration NA=5x10^13 cm^-3. Determine the thermal equilibrium carrier concentration n and p.
Problem 4 (25 points) Consider a silicon pn junction at T-300 K, NA-ND- 1x101° cm3. The minority carrier lifetimes are τ n-0.01 μs and τ p-0.01 us. The junction is forwardbiased with Va 0.6V. The minority carrier diffusion coefficients are Dn-20 cm s, Dp 10 cm Is. n.-1.5x 1010 cm-3 Depletion region n-type p-type a) (10 points) Calculate the excess electron concentration as a function of x in the p side (see the figure above). b) (5 points) Calculate the...
1252 407 3. At 300 K the electron mobility in n-type silicon in cm?N.s can be approximated as un = 88+ - 0.88*n where N is 1+1.26 X 1017 the total ionized impurity concentration /cm? At 300 K the hole mobility in p-type silicon in cm N.s can be approximated as Hp = 54 + 5.88xN where N is the total ionized impurity concentration /cm3. Use these equations to generate plots of electron and hole mobility in silicon as a...
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Problem 4 (25 points) Consider a silicon pn junction at T-300 K, NA-ND- 1x101° cm3. The minority carrier lifetimes are τ n-0.01 μs and τ p-0.01 us. The junction is forwardbiased with Va 0.6V. The minority carrier diffusion coefficients are Dn-20 cm s, Dp 10 cm Is. n.-1.5x 1010 cm-3 Depletion region n-type p-type a) (10 points) Calculate the excess electron concentration as a function of x in the p...
P3. (a) Determine the position of the Fermi level with respect to the intrinsic Fermi level in silicon at T = 300'K that is doped with phosphors atoms at a concentration of 1015 cm. (b) Repeat (a) if the silicon is doped with boron atoms at a concentration of 10'5 cm3. (c) Calculate the electron concentration in the silicon for parts (a) and (b) P1. For the Boltzmann approximation to be valid for a semiconductor, the Fermi level must be...
P4. Find the resistivity at T 300 K for a silicon sample doped with 1 x 10cm of phosphorus (P) atoms, 8.5 x 10 cm of arsenic (As) atoms, and 1.2 x 103 cm3 of boron (B) atoms. Assume that the impurities are completely ionized and the mobilities are μ,-1500 cm2/V-s, μ,-500 cm2/V-s, independent of impurity concentrations. Also assume intrinsic carrier concentration of Si n 1.5 x 10 cm). Hint!!; we can usually use the rule for compensated semiconductors as...