This course focuses on various materials which are used in modern energy conversion devices. Students will gain the basic knowledge of the physical properties, structures, functions, processes, and the evaluation method of those functional energy materials. Specifically, fuel cell materials, high-temperature energy conversion materials, catalytic materials are highlighted, and the state-of-the-art energy devices and related functional materials will be explained. Energy materials are categorized into metals, ceramics, and polymers in term of their carrier conductivity. A role of those functional materials in energy devices will be explained comprehensively. Moreover, students will obtain the knowledge of the relationship between operating principle and the marginal efficiency of the devices and materials functions.
By the end of this course, students will be able to:
1. Explain the basics of fuel cell materials.
2. Explain the basics of high-temperature materials.
3. Explain the basics of secondary battery materials.
4. Explain the similarities and differences among these materials.
Fuel cells, Solar cells, Batteries, High-temperature materials, Catalysts and catalysis, Thermoelectric materials
✔ Specialist skills | Intercultural skills | Communication skills | ✔ Critical thinking skills | ✔ Practical and/or problem-solving skills |
After the guidance of this course, each material will be explained in two classes.
Course schedule | Required learning | |
---|---|---|
Class 1 | Basics of thermal energy and relation between energy materials. Overview of energy materials in terms of high- and low-temperature use. | Explain the relationship between energy materials and thermal energy (temperature). |
Class 2 | Low-temperature materials (separator for secondary batteries and PEFCs) and polymers (cost, machinability, durability) Part 1. | Explain the role of the polymer material as low-temperature materials. |
Class 3 | Low-temperature materials and polymers: Part 2. | Explain the role of the polymer material as low-temperature materials. |
Class 4 | Basics of high-temperature materials. | Explain the type and characteristics of high-temperature materials. |
Class 5 | High-temperature materials and application for thermoelectric power generation. | Explained the principle and characteristics of thermoelectric power generation in relation to high-temperature operation. |
Class 6 | Basics of metal oxide ion and electron conductors. | Explain the type and characteristics of metal oxide ion and electron conductors. |
Class 7 | Characteristics of Carrier conductivity and application to SOFC. | Explain the SOFC principle and performance in relation to carrier conductivity. |
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
There is no textbook. Reading materials will be distributed if needed.
Evaluation will be based on reports. Report assignments are given by lecturers.
No prerequisites.
Be aware of following course modification for FY2020;
(1) The lectures would be given ONLINE (using Zoom system).
(2) The course comprise a total of 7 lectures (the 8th lecture is canceled).
(3) This course is the substitute for canceled "Interdisciplinary Energy Materials Science 2 Suzukakedai".