Solid state physics for understanding the basis of organic optical and electrical materials.
1) Learn important concepts for electronic devices such as electronic states and properties at interfaces.
2) Learn the origin of the dielectric and optical properties of condensed matters.
3) Learn the semi-classical theory of light absorption and emission by molecules.
Following Mat. P301, this course deals with magnetic, dielectric and optical properties of conventional organic semiconductors as well as important concepts for device applications, such as organic transistors, solar cells, and light emitting devices.
Interface, Dielectrics, Optical Properties
✔ Specialist skills | Intercultural skills | Communication skills | Critical thinking skills | ✔ Practical and/or problem-solving skills |
Lecture-based learning. At the beginning of each class, students are given exercise problems related to what was taught in the previous class.
Course schedule | Required learning | |
---|---|---|
Class 1 | Deals with origin of magnetism in solid and five types of magnetism | To explain the principle of constructing ferromagnetic materials with organic materials. |
Class 2 | Deals with surface singular phenomena and surface analysis | To explain the method and measurement principle for observing surface specificity. |
Class 3 | Electronic and V-I characteristics of metal-semiconductor junction | Explain the energy levels and electrical properties of metal-semiconductor junctions. |
Class 4 | Electronic and V-I characteristics of PN junction and working mechanism of bipolar transistors | To explain the energy levels and electrical properties of pn junctions and the principle of operation of transistors. |
Class 5 | Classical theory of light and matter (Lorentz model) and dispersion of dielectric constants | To explain the classical theory of dielectric constant, including dielectric dispersion. |
Class 6 | Classical theory of light and matter (Drude model) including plasma frequency | Explain the classical theory of matter and light (Drude model), including plasma frequencies. |
Class 7 | Dielectric constants and optical properties of matter | To understand the relationship between complex permittivity and complex refractive index, and further explain the calculation method of optical properties of matter. |
Class 8 | Local-field theory and relation between molecular susceptibility and dielectric constants | To understand the concept of local field and to explain the relationship between microscopic polarizability and macroscopic permittivity |
Class 9 | Semiclassical theory of interaction between light and matter | To explain the semiclassical theory of the interaction between matter and light. |
Class 10 | Vibrational and rotational transitions in the framework of the semiclassical theory | To understand the mechanism of vibrational and rotational absorption spectra and to explain the characteristics of the spectra |
Class 11 | Electronic transitions in the framework of the semiclassical theory | To explain the semiclassical theory of electronic spectra |
Class 12 | Optical properties of molecular aggregates | To explain the optical properties of molecular aggregates |
Class 13 | Optical transitions in semiconductors | To explain the optical transitions in semiconductors |
Class 14 | Aspect of organic materials for optical and electrical devices | To explain the characteristics of organic materials as optoelectronic materials |
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.
Hiroshi Saito, et al., Nyumon Kotaibussei, Tokyo, Kyoritsu Shuppan, ISBN4-320-03341-8.(Japanese)
Atkins' Physical Chemistry 10th edition, Oxford University Press. ISBN 978-0-19-9669740-3
By final exam and exercise problems. Details of course scores will be explained in class time.
Students must have successfully completed MAT. P301 and MAT. P302, or have equivalent knowledge.