WSP02300 Quantum Physics

Hiroshima University Syllabus

Japanese

Academic Year 2026Year School/Graduate School Graduate School of Advanced Science and Engineering (Master's Course) Division of Advanced Science and Engineering Quantum Matter Program

Lecture Code WSP02300 Subject Classification Specialized Education

Subject Name 量子物理学

Subject Name
（Katakana）リョウシブツリガク

Subject Name in
English Quantum Physics

Instructor TAKANE YOSITAKE

Instructor
(Katakana) タカネ　ヨシタケ

Campus Higashi-Hiroshima Semester/Term 1st-Year, First Semester, 2Term

Days, Periods, and Classrooms (2T) Tues3-4,Thur3-4：AdSM 405N

Lesson Style Lecture Lesson Style
(More Details) Face-to-face

Lecture

Credits 2.0 Class Hours/Week 4 Language of Instruction J : Japanese

Course Level 5 : Graduate Basic

Course Area（Area） 25 : Science and Technology

Course Area（Discipline） 12 : Electronics

Eligible Students

Keywords

Special Subject for Teacher Education 　 Special Subject 　

Class Status
within Educational
Program
(Applicable only to targeted subjects for undergraduate students)
Criterion referenced
Evaluation
(Applicable only to targeted subjects for undergraduate students)

Class Objectives
/Class Outline This lecture explains the basics and several applications of quantum mechanics.

Class Schedule Comparison with classical mechanics: Ehrenfest's theorem
Comparison with classical mechanics: WKB method 1
Comparison with classical mechanics: WKB method 2
Comparison with classical mechanics: tunneling effect
Quantum finite-size effect: density of states in low-dimensional systems 1
Quantum finite-size effect: density of states in low-dimensional systems 2
Quantum finite-size effect: quantum well laser 1
Quantum finite-size effect: quantum well laser 2
Phase and vector potential: gauge transformation
Phase and vector potential: Aharonov-Bohm effect
Harmonic oscillator: quantization and commutation relations
Harmonic oscillator: quantization of the electromagnetic field 1
Harmonic oscillator: quantization of the electromagnetic field 2
Harmonic oscillator: coherent state 1
Harmonic oscillator: coherent state 2

Text/Reference
Books,etc. Handouts are available on Moodle.

PC or AV used in
Class,etc. Handouts, moodle

(More Details)

Learning techniques to be incorporated

Suggestions on
Preparation and
Review After each lecture, read the corresponding handout to check your understanding.

Requirements A basic knowledge of quantum mechanics, statistical mechanics, and electromagnetism is expected.

Grading Method Evaluation based on homework exercises (80%) and attendance(20%)

Practical Experience

Summary of Practical Experience and Class Contents based on it

Message

Other

Please fill in the class improvement questionnaire which is carried out on all classes.
Instructors will reflect on your feedback and utilize the information for improving their teaching.

Academic Year	2026Year	School/Graduate School	Graduate School of Advanced Science and Engineering (Master's Course) Division of Advanced Science and Engineering Quantum Matter Program
Lecture Code	WSP02300	Subject Classification	Specialized Education
Subject Name	量子物理学
Subject Name （Katakana）	リョウシブツリガク
Subject Name in English	Quantum Physics
Instructor	TAKANE YOSITAKE
Instructor (Katakana)	タカネ　ヨシタケ
Campus	Higashi-Hiroshima	Semester/Term	1st-Year, First Semester, 2Term
Days, Periods, and Classrooms	(2T) Tues3-4,Thur3-4：AdSM 405N
Lesson Style	Lecture	Lesson Style (More Details)	Face-to-face
Lecture
Credits	2.0	Class Hours/Week	4	Language of Instruction	J : Japanese
Course Level	5 : Graduate Basic
Course Area（Area）	25 : Science and Technology
Course Area（Discipline）	12 : Electronics
Eligible Students
Keywords
Special Subject for Teacher Education		Special Subject
Class Status within Educational Program (Applicable only to targeted subjects for undergraduate students)
Criterion referenced Evaluation (Applicable only to targeted subjects for undergraduate students)
Class Objectives /Class Outline	This lecture explains the basics and several applications of quantum mechanics.
Class Schedule	Comparison with classical mechanics: Ehrenfest's theorem Comparison with classical mechanics: WKB method 1 Comparison with classical mechanics: WKB method 2 Comparison with classical mechanics: tunneling effect Quantum finite-size effect: density of states in low-dimensional systems 1 Quantum finite-size effect: density of states in low-dimensional systems 2 Quantum finite-size effect: quantum well laser 1 Quantum finite-size effect: quantum well laser 2 Phase and vector potential: gauge transformation Phase and vector potential: Aharonov-Bohm effect Harmonic oscillator: quantization and commutation relations Harmonic oscillator: quantization of the electromagnetic field 1 Harmonic oscillator: quantization of the electromagnetic field 2 Harmonic oscillator: coherent state 1 Harmonic oscillator: coherent state 2
Text/Reference Books,etc.	Handouts are available on Moodle.
PC or AV used in Class,etc.	Handouts, moodle
(More Details)
Learning techniques to be incorporated
Suggestions on Preparation and Review	After each lecture, read the corresponding handout to check your understanding.
Requirements	A basic knowledge of quantum mechanics, statistical mechanics, and electromagnetism is expected.
Grading Method	Evaluation based on homework exercises (80%) and attendance(20%)
Practical Experience
Summary of Practical Experience and Class Contents based on it
Message
Other
Please fill in the class improvement questionnaire which is carried out on all classes. Instructors will reflect on your feedback and utilize the information for improving their teaching.

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