Materials Physics

Course title

M2053000

Materials Physics

Course description

This course describes the basics of material physics starting from an outline of the various crystal structures, the crystal growth processes, the various defect types found in crystals, the types of dislocations, their nomenclature and their mathematical descriptions. The course will cover processes like diffusion of atoms and crystal defects (voids, interstitial atoms, dislocations) within the crystal lattice, and a thermodynamic description of the processes involved will be given. Several experimental methods employed for the analysis of the composition and the microstructures including X-ray diffraction, electron microscopy and nuclear methods (positron annihilation, muon spin resonance) are discussed. The students will be provided with all knowledge required to understand deformation processes (bending, rolling) of materials.

Purpose of class

The students will be able to learn various crystal structures, the possible crystal defects and their description. The students will understand the principles of diffusion and the thermodynamic description of the processes. The students will be able to learn the analysis methods of the various crystal defects.The students will be provided with all knowledge required to understand the properties of real crystals and the deformation processes (bending, rolling) of materials.

Goals and objectives

	Goals and objectives	Course Outcomes
1.	The students can learn the various crystal structures	A-1
2.	The students can learn the possible crystal defects and their description	A-1
3.	The students can understand the principles of diffusion and the thermodynamic description of the processes	A-1
4.	The students can learn the analysis methods of the various crystal defects	A-1

Language

English

Class schedule

	Class schedule	HW assignments (Including preparation and review of the class.)	Amount of Time Required
1.	Introduction of crystal defects and their importance in deformation processes	Review of the lecture	100分
1.		Read the handouts	90分
2.	Discussion of the various crystal structures and the related properties	Review of the lecture	100分
2.		Read the handouts	90分
3.	Real crystals vs. perfect crystals	Review of the lecture	100分
3.	Real crystals vs. perfect crystals	Read the handouts	90分
4.	Nomenclature of crystal defects and the mathematical description (Burger’s vector)	Review of the lecture	100分
4.		Read the handouts	90分
5.	Dislocations, Frenkel defects, Schottky defects	Review of the lecture	100分
5.	Dislocations, Frenkel defects, Schottky defects	Read the handouts	90分
6.	Exercises – calculation of given problems	Review of the lecture	100分
6.	Exercises – calculation of given problems	Read the handouts	90分
7.	Midterm exam and discussion on the solutions	Preparation for midterm exam	200分
8.	Thermodynamics of crystal defects I	Review of the lecture	100分
8.	Thermodynamics of crystal defects I	Read the handouts	90分
9.	Thermodynamics of crystal defects II	Review of the lecture	100分
9.	Thermodynamics of crystal defects II	Read the handouts	90分
10.	Analysis of microstructures – X-ray techniques	Review of the lecture	100分
10.	Analysis of microstructures – X-ray techniques	Read the handouts	90分
11.	Analysis of microstructures – Electron microscopy	Review of the lecture	100分
11.	Analysis of microstructures – Electron microscopy	Read the handouts	90分
12.	Analysis of microstructures – nuclear methods I (principles)	Review of the lecture	100分
12.		Read the handouts	90分
13.	Analysis of microstructures – nuclear methods II (positron annihilation, muon spin resonance)	Review of the lecture	100分
13.		Read the handouts	90分
14.	Final exam and discussion on the solutions	Preparation for midterm exam	200分
Total.	-	-	2680分

Relationship between 'Goals and Objectives' and 'Course Outcomes'

	midterm exam	final exam	Total.
1.	10%	20%	30%
2.	20%	20%	40%
3.	5%	10%	15%
4.	5%	10%	15%
Total.	40%	60%	-

Evaluation method and criteria

The students will be evaluated based on their:
midterm exam, activity during the class (presentation and discussion) will contribute 40% of the grade, final exam will contribute 60% of the grade.
Students need at least 60% of the full score to pass this course.

Feedback on exams, assignments, etc.

ways of feedback	specific contents about "Other"
Feedback in outside of the class (ScombZ, mail, etc.)

Textbooks and reference materials

1. R.J.D. Tilley, Understanding Solids, Wiley 2013, ISBN 978-1-118-42346-2

2. E.J.Mittemeijer, Fundamentals of Materials Science, Springer 2010, ISBN 978-3-642-10500-5

3. Some scientific papers will be handed out

Prerequisites

Office hours and How to contact professors for questions

Regionally-oriented

Non-regionally-oriented course

Development of social and professional independence

Course that cultivates an ability for utilizing knowledge
Course that cultivates a basic problem-solving skills

Active-learning course

Course by professor with work experience

Work experience	Work experience and relevance to the course content if applicable
N/A	N/A

Education related SDGs:the Sustainable Development Goals

4.QUALITY EDUCATION
9.INDUSTRY, INNOVATION AND INFRASTRUCTURE

Last modified : Sat Sep 09 08:02:58 JST 2023