Problem 4 (25 points) Consider a silicon pn junction at T-300 K, N,-1x1017 ст?, ND-11016 Cm -, The minority carrier lifetimes are τ u-^ 1 μs and τ p-1 μs. The minority carrier diffusion coefficients...
Problem 3 (25 points) Consider a silicon pn junction at T - 300 K, NA- 1016 cm3, ND-5x1016 cm-3. The minority carrier lifetimes are τα , τ,-1 us. The junction is forward biased with Va-0.5V The minority carrier diffusion coefficients are D 25 cm/s, Da- 10 cm2/s n,1.5x1010 cm3 kT 0.0267 Depletion region p-type n-type a) (5 points) Calculate the excess electron concentration as a function of x in the p-side (see the figure above) b) (10 points) Calculate the...
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...
Can someone help solve this question step by step? Thanks! 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...
Consider a silicon pn junction at T = 300 K, NA-Np - 4x106cm. The minority carrier lifetimes are tn = Tp=1 us. The junction is forward biased with V, -0.6V. The minority carrier diffusion coefficients are D = 20 cm²/s, D = 10 cm²/s. n;= 1.5x100cm, kt/e = 0.026V Depletion region n-type p-type a) (5 points) Do we have low-level injection? b) (10 points) Calculate the electron concentration at x = -(Xp + Ln) where L, is the electron diffusion...
Problem 4 (25 points) Consider a silicon pn junction at T 300 K, NA ND-1x1016 cm3. The minority carrier lifetimes are τ -0.01 μs and τΡ 0.01 μ. The Junction is forwardbiased with , V,-0.6V. The minority carrier diffusion coefficients are D,-20 cm2/s, D,-10 cm2/s. n, = 1.5x 1010cm -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...
3. A silicon step junction has uniform impurity doping concentrations of N. 5 x 1015 cm-3 and Nd = 1 x 1015 cm-, and a cross-sectional area of A-|0-4 cm2. Let tao -0.4 s and tpo 0.1 us. Consider the geometry in Figure.Calculate (a) the ideal reverse saturation current due to holes, (b) the ideal reverse saturation current due to electrons, (c) the hole concentration at a, if V V and (d) the electron current at x = x" +...
A silicon pn junction at T = 300 K has the following parameters: Na-5 1016 cm-?, N,-1 1016 cm-3, D.-25 cm3/s, D.-10 cm2/s, ?,0-5 x 10-7 s, and To 1 X 10-7 s. The cross-sectional area is A 10-3 cm2 and the forward- bias voltage is V,-0.625 V. Calculate the (a) minority electron diffusion cur- rent at the space charge edge, (b) minority hole diffusion current at the space charge edge, and (c) total current in the pn junction diode.
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", ,...
Problem 1 (25 points) Consider a silicon pn junction with a cross section area of 1x105 cm, a forward bias Va 0.5V, and the following parameters at T- 300K: 16cm-3 15 3 -6 KT n: 1.5x100 cm", ε' = 1 1 .7x 8.854x 10-14 Flon;ー-0.025 V Assume the critical field to be equal to 3x105 V/cm. a) (5 points) Compare the hole density at xn to the electron density at-Xp b) (5 points) Compare the hole current at xn to...