Q5) A Germanium pn junction has a hole density in is p-side 102ªm-3 and an electron density in n-side is 1022 m-3, the cross-section area for the pn junction is 10-6m², Determine: 1) The density of majority and minority carriers and the conductivity? 2) The barrier potential? 3) Saturation current? 4) The junction current at Vp = 0.25V? 5) The junction current for the reverse bias, at high reverse voltage? Note that: n = 2.5 × 101ºm-3,µp = 0.16 m²/V.s and µn = 2.25µp. (Ln = 300µm and Lp = 200µm), at room temperature %3D List of constants: Charge of electron=1.6x10""C. Permittivity of space = 8.85×10*1² F/m Boltzmann constant =1.38x10 J/°K Mass of electron = 9.1×10³'Kg. Plank's constant = 6.626×10*ª J. s. Speed of light=3.0x10* m/s %3D

Q5) A Germanium pn junction has a hole density in is p-side 102ªm-3 and an electron density in n-side is 1022 m-3, the cross-section area for the pn junction is 10-6m², Determine: 1) The density of majority and minority carriers and the conductivity? 2) The barrier potential? 3) Saturation current? 4) The junction current at Vp = 0.25V? 5) The junction current for the reverse bias, at high reverse voltage? Note that: n = 2.5 × 101ºm-3,µp = 0.16 m²/V.s and µn = 2.25µp. (Ln = 300µm and Lp = 200µm), at room temperature %3D List of constants: Charge of electron=1.6x10""C. Permittivity of space = 8.85×101² F/m Boltzmann constant =1.38x10 J/°K Mass of electron = 9.1×10³'Kg. Plank's constant = 6.626×10ª J. s. Speed of light=3.0x10* m/s %3D

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

See similar textbooks

Similar questions

A diffused silicon PN junction has a linearly graded junction in the P-side with ?=10^19cm−3, and a uniform doping of 3×10^14 cm−3on the N-side. If the depletion layer width of the P-side is 0.8μm at zero bias, find the total depletion layer width, built-in potential, maximum field at zero bias and sketch the potential distribution.
Assume D = D0e^–Ea/kT is the diffusion coefficient of boron in silicon surface, whereD0 = 10.5 cm^2/s and Ea = 3.7 eV. The substrate is N-type silicon doped to 10^15 cm^3.N0 = 10^15 cm^2 of boron is introduced just below the silicon surface.(a) What is the junction depth after a 1-h drive-in at 1,100°C?(b) By how much will the junction depth change after 10^6 h (~100 years) of operation at100°C
You are given an intrinsic silicon at "some" temperature. Assume that the intrinsic Fermi level, E, is exactly at the middle of the of the conduction band edge, Ec, and the valence band edge, Ev. It is known that the Fermi-Dirac probability for electrons at the conduction band edge is fe(E) = 5×102 at the unknown temperature. 1. What is the probability to find holes fh(Ec) at the conduction band edge?2. What is the Fermi-Dirac probability for electrons at the valence band edge, fe(Ev)?3. What is the Fermi-Dirac probability for holes at the valence band edge, fh(Ev)?
Estimate the amount of free electrons and holes in a N-doped Silicon wafer a) at room temperature with 1014 cm-3 doping level, and b) at 650K with 1015 cm-3 doping level
If the hole mobility in a sample of silicon doped P-type is 108.0 cm^2/Vs at 275°K, then what is the diffusion constant for holes at this same temperature in cm^2/s? (Hint: Remember that kT/q = 26mV at 300°K, and use this to find the value for kT/q at 275°K.)
Assume a cylindrical diode, half P doped and half N doped. If the diode diameter is 100um, calculate the following: a) Junction capacitance for no external bias and ND = 1E16 atoms/cm3 and NA = 1E16 atoms/cm3 b) Junction capacitance for no external bias and ND = 1E17 atoms/cm3 and NA = 1E15 atoms/cm3 c) Junction capacitance for a 10V reversed voltage and ND = 1E17 atoms/cm3 and NA = 1E15 atoms/cm3 d) Junction capacitance for a 0.3V forward voltage and 1E16 atoms/cm3 and NA = 1E16 atoms/cm3
A certain PN junction has a linearly graded junction on the p-side, Na = ax, where x is the distance from the physical junction to p-side and a = 1019 cm-4 , and a uniform doping of 3 x 1014 cm-3 on the n-side. It is operated at T=300K. A. Calculate the electric field as a function of x? B. If the depletion layer width of the p-side is .8um at zero bias, find the total depletion layer width
The linear electron and hole concentration profiles in a 4 um wide region of silicon material is shown in the figure below. The silicon material is subjected to electron injection from the left and hole injection from the right as shown in the figure. Assume that the cross-sectional area of the material ?=1 ??2, electron mobility ??=1312.75 ??2/? ?, and hole mobility ??=463.33 ??2/? ?. Find the total current (to one decimal place) flowing through the material. ?=300?, ?=1.6×10−19 ?, ?=8.62×10−5 ??/?, ?=1.38×10−23 ?/?, and 1 ??=1.6×10−19 ?. Explain how depletion and diffusion capacitances differ
You are given an intrinsic silicon at "some" temperature. Assume that the intrinsic Fermi level, E, is exactly at the middle of the of the conduction band edge, Ec, and the valence band edge, Ev. It is known that the Fermi-Dirac probability for electrons at the conduction band edge is fe(E) = 5×102 at the unknown temperature. 1.What is the Fermi-Dirac probability for electrons at the intrinsic Fermi level, fe(Ei)?
"In the PN junction shown below, the charges of the depletion region are due to? "this is the question ????
3. Consider a silicon with intrinsic carrier concentration ni of 1010 cm-3 at room temperature.It is then doped to p-type doping with a concentration of NA = 5x1017 cm-3. What is thelocation of the Fermi level relative to the conduction band? (Hint: NC = 2.8x1019 cm-3).
Calculate the drift current in silicon at room temperature. If the intrinsic carrier concentration of (1×1016electron/m³) with the doping concentration of (2×1016atoms/m³) of the phosphorus and (1×1016atoms/m³) of Boron. Given the mobility for the electrons (0.15m2/V.s), the mobility for the holes (0.05m2/V.s), the electric field (100V/m), and the cross section area is 1mm?.