2. Determine the highest energy bandgap of each ternary semiconductor at which the semiconductor is sensitive to the given radiation wavelength. Calculate the corresponding value of the mol fraction x. 3. For each ternary semiconductor, for the value of the energy bandgap determined in step 2, calculate the thermal equilibrium electron concentration by numerically evaluating the integral in equation (3). Mention any assumption you make. 4. Identify the selected semiconductor which will have higher sensitivity. Two materials are Ga_xln_(1-x)As & GaAs (1-x)Sb_x. Wavelength is 1.24um.

2. Determine the highest energy bandgap of each ternary semiconductor at which the semiconductor is sensitive to the given radiation wavelength. Calculate the corresponding value of the mol fraction x. 3. For each ternary semiconductor, for the value of the energy bandgap determined in step 2, calculate the thermal equilibrium electron concentration by numerically evaluating the integral in equation (3). Mention any assumption you make. 4. Identify the selected semiconductor which will have higher sensitivity. Two materials are Ga_xln_(1-x)As & GaAs (1-x)Sb_x. Wavelength is 1.24um.

Electric Motor Control

10th Edition

ISBN:9781133702818

Author:Herman

Publisher:Herman

Chapter59: Motor Startup And Troubleshooting Basics

Section: Chapter Questions

Problem 12SQ: How is a solid-state diode tested? Explain.

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