Fundamentals of optics and optical properties of matters are lectured for the students who majors in electronics and applied physics. It is also open for the students in other departments who are interested in the optics and optical properties of matters. The lecture is divided into three parts: (a) electromagnetic wave and matter by Prof. Kajikawa (b) fundamentals of quantum optics by Prof. Ito and (c) photoelectric conversion devices by Prof. Iino. In (a), the students learn light propagation in a matter, refractive index, polarization, light reflection and refraction, optical waveguide, optical fiber and spectroscopy. In (b), we quantize electric magnetic fields and examine photon number states and coherent states using an operator method. Then, we learn the relation between atomic energy structures and orbital and spin angular momenta, and solve selection rules on optical transitions. We also learn the fundamentals of laser oscillation. In (c), students will learn the fundamentals of light emitting and photodetecting devices through lectures on the principles of photo carrier generation and light emission in inorganic and organic semiconductors.
This lecture is for the students in Department of Electrical and Electronic Engineering. The students belonging to other courses are also recommended to have this lecture who are going to learn Fundamentals of Light and Matter IIa, IIb and IIc.
The students will understand：
(a) propagation in a matter, refractive index, polarization, light reflection and refraction, optical waveguide, optical fiber and spectroscopy.
(b) algebraic calculations with creation and annihilation operators, photon number states and coherent states, label of atomic energy levels with angular momenta, selection rules, and lasing property.
(c) the differences in the mechanisms of photocarrier generation in inorganic and organic semiconductors.
refractive index, optical waveguide, light reflection and refraction, spectroscopy, quantum optics, laser, semiconductor, light emitting diodes, photo-diodes
|✔ Specialist skills||Intercultural skills||Communication skills||Critical thinking skills||Practical and/or problem-solving skills|
After the lecture, students will have exercise problems.
|Course schedule||Required learning|
|Class 1||propagation in a matter, refractive index, polarization||Understand the origin of refractive index and polarization|
|Class 2||phase velocity and group velocity, light reflection and refraction.||Understand phase velocity and group velocity, light reflection and refraction|
|Class 3||total reflection and optical waveguide.||Understand total reflection and optical waveguide|
|Class 4||optical fiber||Understand the optical fiber and optical mode|
|Class 5||infrared spectroscopy, visible light spectroscopy||Understand the principles of the spectroscopy methods|
|Class 6||Raman spectroscopy, photoelectron spectroscopy||Understand the principles of the spectroscopy methods|
|Class 7||quantization of light||Quantize electric magnetic fields|
|Class 8||photon number states and coherent states||Understand calculations with creation and annihilation operators and optical quantum states.|
|Class 9||atomic energy and angular momentum||Express atomic energy levels with angular momenta.|
|Class 10||optical transition||Solve energy level splits due to the spin-orbital interaction and selection rules on photon absorption and emission.|
|Class 11||stimulated emission and population inversion||Understand the stimulated emission and the population inversion for lasers.|
|Class 12||laser oscillation||Understand the principle of laser oscillation.|
|Class 13||Light emitting devices||Understanding the principle of operation of light emitting devices|
|Class 14||Photodetecting devices||Understanding excitons during photocarrier generation|
To enhance effective learning, students are encouraged to spend approximately 100 minutes preparing for class and another 100 minutes reviewing class content afterwards (including assignments) for each class.
They should do so by referring to textbooks and other course material.
None. In (b), a lecture note is distributed.
G. R. Fowles: Introduction to Modern Optics, Dover ISBN0-486-65967-7
C. Kittel: Introduction to Solid State Physics (either 6, 7, 8th edition), (8th ed. ISBN-10: 0471111813)
Students' knowledge of optics and optical properties of matters, and their ability to apply them to problems will be assessed.
Final exams approx 70%, exercise problems 30%.
The final exam will be made in a face-to-face manner (not on-line).
Classes will be conducted remotely (live-type). If necessary, recorded video will be used for part of the class.