could you please explain the steps to solve as best as possible please?
could you please explain the steps to solve as best as possible please? 1. At T300K,...
4. AP-N abrupt junction is formed in Silicon as follows: The P-side has a uniform acceptor concentration of 2E18/cm^3 and the N-side has a uniform donor concentration of 2E15/cm^3. (a) Find the built-in voltage, V of the P-N junction at 300K. (b) Find the width of the depletion regions in the P and N regions of the transition region for zero reverse bias and for 5V reverse bias. (c) What is the depletion capacitance per unit area with zero reverse...
XXX is 467 Design an ideal abrupt silicon PN-junction at 300 K such that the donor impurity concentration in the n-side N, = 5x1015 cm3 and the acceptor impurity concentration in the p-side N, = XXX × 1015/cm3 Assume that the diode area A-2x10-3 cm2 and 100cm work Note that the values obtained in the calculations may not be realistic as the Matric # varies greatly. The assignment is only to test your understanding, and must be handwritten Determine the...
(iv) [2 Marks] A pn-junction has a built-in potential voltage of 1V across the junction. The width of the depletion region is 1um. The acceptor doping is NA 2 x 1015cm-3 in the P-side and a donor doping is Np = 8 x 1015cm-3 on the N-side. If the reference position x 0 is the edge of the depletion region on the P-side and the P region is on the left of the N region then where does the maximum...
Biased Sip-n junction A Si p-n junction with area of 0.001 cm* is formed with an acceptor concentration of Na 1x1015 cm3 on the p-side and a donor concentration of Na- 1x10" cmon the n-side. Calculate at 300 K (a) the diffusion voltage VD (b) the space charge width at equilibrium and with zero bias (c) the current with forward bias of 0.5 eV. Assume that the current is diffusion dominated. The electron and hole mobilities are ln-1500 cm2/(Vs) and...
Consider an abrupt p-n diode - made of an unknown semiconductor - in thermal equilibrium with as many donors in the n-type region as acceptors in the p-type region and a maximum electric field of -13 kV/cm and a total depletion layer width of 1 µm. (assume es/ e0 = 12) a) What is the applied voltage, Va? b) What is the built-in potential of the diode? c) What are the donor density in the n-type region and the acceptor...
2. (60 pts) Consider a one-sided silicon PN diode. The p-side is degenerately doped (and you can assume Ep = Ey for simplicity). The doping concentration on the n-side is Np for 0<x <too. The depletion width on the n-side is xn. Use the depletion approximation. p* ND x 0 From here, you assume that Np is given by 4x1015 cm. (h) (7 pts) What is the maximum electric field in depletion region when Va=-3 V? (i) (8 pts) As...
2 photos The depletion layer width for different junctions is given by the following equations: w = het w = jane te pare VO w = (1280XL) Intrinsic carrier concentration of silicon, n., is 9.65 x 10 cm 1) The expressions for minority carrier diffusion length and diffusion coefficients and thermal velocity are as follows (for n-and p-type materials). L. - (Dpt) La = (Dat)* Và = To 1/NA in p-type material 1 - 1/(RexNA), where Re is the recombination...
The question is attached here in the form of an imagecm2] flowing through this diode under an applied forward bias of V = 0.6 V the edges of the depleion region. diode at room temperature with an applied forward bias of V 0.6 V. forward bias of V = 0.6 V. PROBLEM E1-PHYSICAL ELECTRONICS II Consider a p-n junction similar to the one depicted in the schematic p-n junction below but with NA 10's cm3 and No- 1016 cm3. At...
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...
1. Draw the schematics of forward-biased and negative-biased diodes. Show the polarity of voltage source (positive and negative terminal of the source), the position of Fermi levels and the current direction. Explain why there is a small current flow when a p-n junction is under reverse bias. 2. A p-n junction can be made by diffusing acceptor atoms into an n-type semiconductor. Suppose that boron is diffused into a silicon wafer doped with arsenic at 1015 cm-3 such that the...