Fundamentals of Materials Science
- Offered byCoursera
- Public/Government Institute
Fundamentals of Materials Science at Coursera Overview
Duration | 20 hours |
Total fee | Free |
Mode of learning | Online |
Schedule type | Self paced |
Difficulty level | Intermediate |
Official Website | Explore Free Course  |
Credential | Certificate |
Fundamentals of Materials Science at Coursera Highlights
- 100% online Start instantly and learn at your own schedule.
- Flexible deadlines Reset deadlines in accordance to your schedule.
- Intermediate Level Undergraduate/graduate students, with knowledge in calculus and college physics (mechanics and thermodynamics)
- Approx. 20 hours to complete
- English Subtitles: English
Fundamentals of Materials Science at Coursera Course details
- Materials are the physical foundations for the development of science and technology. The human civilizations are historically designated by the evolution of materials, such as the Stone Age, the Bronze Age and the Iron Age. Nowadays, materials science and technology support most of the industrial sectors, including aerospace, telecommunications, transportation, architecture, infrastructure and so on. Fundamentals of Materials Science is a core module for undergraduates majored in materials science and engineering. This English course will be taught by Prof. Guo Qiang, Prof. Reddy and Prof. Liu Jing from Shanghai Jiao Tong University. An integrated approach of combining metallic, ceramic and polymeric materials will be adopted in this course, for the attendants to attain a deep understanding on the correlation of composition, microstructure, processing and properties in materials science. Let?s gather in this course and explore the wonderland of materials together.
Fundamentals of Materials Science at Coursera Curriculum
Week 1
Course advertisement
Course introduction
1.1 Atomic bonding
1.2 Crystal lattice
1.3 Crystal structure of metals
Problem set 1
Week 2
1.4 Crystallographic points, directions & planes
1.5 Crystal structure of ceramics
1.6 Polymorphism & allotropy
1.7 Structure of polymers
1.8 Characterization of crystal structure
Problem set 2
Week 3
2.1 Equilibrium concentration of point defects
2.2 Point defects in ionic solids
2.3 Concept of dislocations
2.4 Geometry of dislocations
Problem set 3
Week 4
2.5 Dislocations in real crystals
2.6 Motion of dislocations
2.7 Elastic properties of dislocations
2.8 Forces on dislocations
2.9 Surfaces & interfaces
Problem set 4
Week 5
3.1 Stress strain curves
3.2 Elastic & viscoelastic properties
3.3 Slip mechanism
3.4 Twinning & kinking
Problem set 5
Week 6
3.5 Grain refinement
3.6 Solid solution strengthening
3.7 Second phase & work hardening
3.8 Property evolution
Problem set 6
Week 7
3.9 Mechanical properties of ceramics (1)
3.10 Mechanical properties of ceramics (2)
3.11 Mechanical properties of polymers
3.12 Introduction of composites
3.13 Mechanical properties of composites
Problem set 7
Week 8
4.1 Kinetics of recovery and recrystallization (1)
4.2 Kinetics of recovery and recrystallization (2)
4.3 Grain growth after recrystallization
4.4 Dynamic recovery and dynamic recrystallization
Problem set 8
Week 9
5.1 Diffusion phenomena
5.2 Fick's law
5.3 Solutions to diffusion functions
5.4 Kirkendall & Darken
Problem set 9
Week 10
5.5 Thermodynamics of diffusion
5.6 Atomic mechanisms of diffusion
5.7 Factors that affect diffusion (1)
5.8 Factors that affect diffusion (2)
Problem set 10
Week 11
6.1 Basics of phase diagrams
6.2 Thermodynamics of phase diagrams
6.3 Effect of pressure on free energy
6.4 Free energy of binary systems
Problem set 11
Week 12
6.5 Graphic construction of phase diagrams
6.6 Gibbs phase rule
6.7 Construction of phase diagrams
6.8 Evolution of different phase diagrams
Problem set 12
Week 13
6.9 Spinodal decomposition
6.10 Lever rule
6.11 Binary phase diagrams
6.12 Steels
Problem set 13
Week 14
6.13 Cast irons
6.14 Three-component systems (ternary phase diagrams) (1)
6.15 Three-component systems (ternary phase diagrams) (2)
6.16 Three-component systems (ternary phase diagrams) (3)
Problem set 14
Week 15
7.1 Phase transformations basics of solidification
7.2 Nucleation
7.3 Heterogeneous vs homogenous nucleation
7.4 Temperature time transformation
Problem set 15
Week 16
7.5 Phase transformations in steels (1)
7.6 Phase transformations in steels (2)
7.7 Phase transformations in alloy steels
7.8 Precipitation
7.9 Precipitation in Al alloys
Problem set 16
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