| Course title | |||||
| 物理実験学 [Methodology of Experimental Physics] | |||||
| Course category | technology speciality courses,ets. | Requirement | Credit | 2 | |
| Department | Year | 3~4 | Semester | 3rd | |
| Course type | 3rd | Course code | 023620 | ||
| Instructor(s) | |||||
| 森下 義隆, 内藤 方夫, 稲場 肇 [MORISHITA Yoshitaka, NAITO Michio, INABA Hajime] | |||||
| Facility affiliation | Faculty of Engineering | Office | afjgxte/L1151 | Email address | |
| Course description |
| The basic principles and techniques required for physics experiments is learned. The course includes basic concepts of measurements, accuracy of measurements, systems of units, standards, basic physics parameters, sample preparation technology, vacuum technology, and cryogenic technology and. These are the basics that are required in experiments performed by graduation research in the fourth year |
| Expected Learning |
|
Students are expected to learn (1) concept of accuracy or uncertainty of measurements. (2) systems of units and measurement standards. (3) basics of sample preparation. (4) cryogenic technology, namely how to reach low temperature required for experiments below 4.2 K and how to measure temperatures. (5) vacuum technology, namely how to reach high (10-1~10-5 Pa) or ultrahigh vacuum (10-5~10-9 Pa) and how to measure low pressures. Based on the knowledge, students are expected to design and perform proper experiments. Corresponding criteria in the Diploma Policy: See the Curriculum maps |
| Course schedule |
|
** 1?6th. Dr. Yasuda 1. Introduction and basic concept of measurements (1): what is a measurement?. 2. Basic concept of measurements (2): accuracy, error, uncertainty in measurements 3. Basic concept of measurement (3): international system of units (SI) and basic physical parameters 4. SI units (1): length standard 5. SI units (2): time and frequency standards 6. SI units (3): mass, electricity, and temperature standards ** 7?10th. Dr. Morishita 7. Sample preparation (1): thermochemistry (reaction heat, reaction rate, chemical equilibrium, and law of mass action) 8. Sample production (2): thermochemistry and solution layer growth 9. Sample production (3): Vapor phase growth (vacuum spraying and MBE) 10. Sample production (4): Sample evaluation ** 11?15th. Dr. Naito 11. Cryogenic technology (1): basics and history of cryogenics 12. Cryogenic technology (2): how to reach low temperature down to liquid helium temperature (4.2 K). 13. Cryogenic technology (3): how to reach low temperature below liquid helium temperature (4.2 K). 14. Vacuum technology (1): how to reach high (10-1~10-5 Pa) or ultrahigh vacuum (10-5~10-9 Pa). 15. Vacuum technology (2): how to measure low pressures. |
| Prerequisites |
| Physical Chemistry, Thermodynamics and Statistical Mechanics |
| Required Text(s) and Materials |
| References |
|
Masami Yasuda, “Who determines 1 sec? From a sundial to an optical lattice clock (Chikuma shobou ) Charles Kittel, “Thermal Physics” (W. H. Freeman and Company) |
| Assessment/Grading |
| Based on the sum of the scores for the reports on the tasks given by teachers. |
| Message from instructor(s) |
| Course keywords |
| Office hours |
| From 12:00 to 13:00 on Friday |
| Remarks 1 |
| Remarks 2 |
| Related URL |
| Lecture Language |
| Language Subject |
| Last update |
| 1/6/2020 10:40:44 AM |