Semiconductor Devices

Course title

G0914400

Click to show questionnaire result at 2018

Course description

Semiconductor devices such as transistors are widely used for electronic systems. In this course, students will learn semiconductor device fundamentals such as energy bands of semiconductors, carrier conduction mechanism, p-n junctions, bipolar transistors, power devices, metal-oxide-semiconductor (MOS) structures, MOS field effect transistors (FETs), metal-semiconductor contacts, metal-semiconductor FETs. （Japanese students of the SIT Department of Electronic Engineering should take another class in Japanese.)

Purpose of class

To learn the basics, structures, operation principles, and characterictics of semiconductor devices and integrated circuits such as bipolar transistors, thyritors, MOS diodes, MOSFETs, MESFETs, and LSIs.

Goals and objectives

Can explain fundamental semiconductor physics such as energy band, carrier conduction in semiconductors, and pn junctions.
Can explain operation principles and characteristics of p-n junction and Schottky diodes using band diagram.
Can explain structures, band diagram, operation principles, and device characteristics of bipolar devices such as bipolar transistors, thyristor, and power devices.
Can explain structure, band diagram, carrier distribution, C-V characteristics, and threshold voltage. Can explain structures and operation principle of MOSFET.
Can explain fundamental structure, devices, and fabrication process of LSIs. Can explain structures and features of advanced transistors.

Language

English

Class schedule

	Class schedule	HW assignments (Including preparation and review of the class.)	Amount of Time Required
1.	Introduction History and trend of semiconductor devices and integrated circuits.	Read Chapter 0 of textbook. Review hand-out.	190minutes
2.	Energy bands of semiconductors Origin of band structure and how they are related to the motion of electrons in semiconductor materials such as Si and GaAs.	Read Chapter 1.1-.4, Review hand-out.	190minutes
3.	Carrier concentration Relation between Fermi level and carrier concentration in thermal equilibrium. Fermi level changes with doping and temperature.	Read Chapter 1.5-.6. Review hand-out.	190minutes
4.	Carrier transport phenomena (1) drift and diffusion Mechanism of drift and diffusion.	Read Chapter 2.1-.2, Review hand-out.	190minutes
5.	Carrier transport phenomena (2) other transport process Other transport phenomena such as generation and recombination, thermionic emission, and tunneling. Current continuity equation., Report(1)	Read Chapter 2.3-6, Review hand-out.	190minutes
6.	p-n　junction　(1)　 Band diagram of p-n junction, depletion region, and the depletion capacitance.	Read Chapter 3.1-3, Review hand-out.	190minutes
7.	p-n　junction　(2)　Midterm quiz Current-voltage characteristics of p-n junction, junction breakdown, and heterojunction.	Read Chapter 3.4, 6, 7, submit report-1	190minutes
8.	Bipolar transistor Operation principle and characteristics of bipolar transistors. Heterojunction bipolar transistors.	Read Chapter 4.1-5, Review hand-out.	190minutes
9.	Power devices Operation principle of power devices such as thyristors, BTO, and IGBTs.	Read Chapter 4.6, Review hand-out.	190minutes
10.	MIS capacitor Ideal MIS capacitor, SiO2/Si MOS capacitor Non-ideal MOS capacitor, current transport in insulator	Read Chapter 5.1,2, 3, Review hand-out.	190minutes
11.	MOSFET Fundamental MOSFET, various kinds of MOSFETs	Read Chapter 5.5, Review hand-out.	190minutes
12.	Advanced MOSFET MOSFET scaling, CMOS, SOI, MOS memory devices Report (2)	Read Chapter 6, Review hand-out.	190minutes
13.	MESFET and related devices Metal-semiconductor contacts, MESFET operation principle, MODFET	Read Chapter 7, Review hand-out.	190minutes
14.	Final examination and its explanation	Review the handouts, submit report-2	190minutes
Total.	-	-	2660minutes

Relationship between 'Goals and Objectives' and 'Course Outcomes'

	Midterm quiz	Final exam	Report(1)	Report(2)	Total.
1.	15%	0%	15%	0%	30%
2.	10%	0%	10%	0%	20%
3.	0%	10%	0%	10%	20%
4.	0%	10%	0%	10%	20%
5.	0%	5%	0%	5%	10%
Total.	25%	25%	25%	25%	-

Evaluation method and criteria

Midterm quiz 25% Final Examination 25%, Report(1) 25%, Report(2) 25% pass by 60 % achievement. Criteria of 60% is that students can solve the problems and answer the questions in the quiz, exam, and report problems about 60 %.

Feedback on exams, assignments, etc.

ways of feedback	specific contents about "Other"
Feedback in the class

Textbooks and reference materials

“Semiconductor Devices, Physics and Technology, 3rd edition” S. Sze and M. Lee, Wiley.

Prerequisites

Knowledge of fundamental electromagnetic theory, quantum mechanics, and solid state physics.

Office hours and How to contact professors for questions

Monday 12:30-13:10 at Zoom
Please make a contact in advance by email to get the Zoom information.

Regionally-oriented

Non-regionally-oriented course

Development of social and professional independence

Course that cultivates a basic problem-solving skills

Active-learning course

More than one class is interactive

Course by professor with work experience

Work experience	Work experience and relevance to the course content if applicable
Applicable

Education related SDGs:the Sustainable Development Goals

9.INDUSTRY, INNOVATION AND INFRASTRUCTURE

Last modified : Sat Sep 09 06:44:19 JST 2023