For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| EAM3076 | Convergence materials for flexible and printed electronics | 3 | 6 | Major | Bachelor | 3-4 | - | No | |
| As the future of electronics is rapidly shaping up, the two key words has recently surfaced up: flexible and printed electronics. The class starts with introduction on a new class of materials that enable flexible and printed electronics, such as organic materials and nanomaterials. Further discussion includes understanding on emerging devices based on these technologies. | |||||||||
| EAM3078 | Advanced Materials Design(Capstone Design) | 3 | 6 | Major | Bachelor | 3-4 | English,Korean | Yes | |
| In this class, advanced theoretical knowledge of material composition/microstructure/processing techniques are covered, and students are required to design new material system and processing procedure to meet the given physical properties. | |||||||||
| EAM3080 | Materials Interface Science | 3 | 6 | Major | Bachelor | 3-4 | English | Yes | |
| This course is a undergraduate level course in interface science and materials engineering. Materials interface have various types of interfaces including solid/solid, solid/liquid, and solid/liquid which are basic interfaces for doping, dispersion, solution coating, and vapor deposition. Understanding the basics of interface chemistry/physics and their relationship with material processing parameters and final material’s properties is a final goal of this course. | |||||||||
| EAM3081 | Semiconductor Devices | 3 | 6 | Major | Bachelor | 3-4 | - | No | |
| Solid state devices like transistors have evolved from an interesting laboratory experiment to a technology with applications in all aspects of modern life. The basics of MOSFET though solid state semiconductor devices can be understood by using some elementary concepts of MOS and Field-effect Transistor. This course provides this framework to analyze bipolar junction transistors (Shockley, 1953) and modern MOSFET (FinFET, Thin-Film Transistor, and RF transistor), and introduces the basic principle and application of digital/analogy devices. | |||||||||
| EAM3082 | Optoelectronic Device Fundamentals | 3 | 6 | Major | Bachelor | 3-4 | Korean | Yes | |
| The class aims to introduce the operation principles of optoelectronic devices and their applications. The propagation characteristics of light such as the reflection, refraction, diffraction, and interference, the optical properties of materials and their microscopic structures, the polarization of light, and the photometry will be introduced first. The operation principles of the multilayer mirrors, resonators, liquid crystals, solar cells, photodiodes, light emitting diodes, lasers, polarizers, electro-optic modulators will be introduced as the practical applications of optoelectronic devices. | |||||||||
| EAM3083 | Introduction to Metallography | 3 | 6 | Major | Bachelor | 3-4 | - | No | |
| A review will be presented of basic theory and statistical analysis, with particular emphasis on terms and definitions of a microstructure. Relationships between the processing of metals, the microstructure and the properties of metal components will be emphasized. The last half of the course will cover applications of quantitative metallography to problems in failure analysis, solidification, heat treatment, and deformation behavior. | |||||||||
| EAM3084 | Startup Practice in Materials Science & Engineering1 | 3 | 6 | Major | Bachelor | 3-4 | - | No | |
| In this course, students will learn how to apply their knowledge about science and engineering of materials to business start-ups. ※ This course is a curriculum that recognizes Startup Activity as a credit. This course is recognized as a credit when it is possible to achieve the learning goal through establishment. Only students who start-up can take classes. Only students who are approved according to the procedures of the school can take courses in the field trips. Be sure to check the requirements and procedures before taking this course. | |||||||||
| EAM3085 | Startup Practice in Materials Science & Engineering2 | 6 | 12 | Major | Bachelor | 3-4 | - | No | |
| In this course, students will learn how to apply their knowledge about science and engineering of materials to business start-ups. ※ This course is a curriculum that recognizes Startup Activity as a credit. This course is recognized as a credit when it is possible to achieve the learning goal through establishment. Only students who start-up can take classes. Only students who are approved according to the procedures of the school can take courses in the field trips. Be sure to check the requirements and procedures before taking this course. | |||||||||
| EAM3086 | Startup Practice in Materials Science & Engineering3 | 9 | 18 | Major | Bachelor | 3-4 | - | No | |
| In this course, students will learn how to apply their knowledge about science and engineering of materials to business start-ups. ※ This course is a curriculum that recognizes Startup Activity as a credit. This course is recognized as a credit when it is possible to achieve the learning goal through establishment. Only students who start-up can take classes. Only students who are approved according to the procedures of the school can take courses in the field trips. Be sure to check the requirements and procedures before taking this course. | |||||||||
| EAM3088 | Understanding of Advanced Materials Characterization | 3 | 6 | Major | Bachelor | 3-4 | English,Korean | Yes | |
| With the suggestion of various advanced devices, the understanding of the methods to utilize advanced materials characterization tools is also essential in the field of materials science and engineering. This class is to study the fundamental knowledge on analysis instruments with various materials, to distinguish pros and cons of individual tools, and finally perform the characterizatio of the real examples. This study is available to apply in the field study of research and industry. | |||||||||
| EAM3089 | Experiments of Materials Processing | 3 | 6 | Major | Bachelor | 3 | Korean,English | Yes | |
| This course is aimed to provide opportunities for students enrolled in the School of Materials Science and Engineering to carry out experiments on manufacturing or synthesis of metallic materials, ceramic materials, and nanomaterials, so that they can understand basic processing of materials. | |||||||||
| EAM3090 | Experiments of Material Analyses | 3 | 6 | Major | Bachelor | 3 | English | Yes | |
| This course provides an experimental opportunity for students enrolled in the School of Materials Science and Engineering to measure some of the important properties of materials, such as conductivity and mobility, and analyze the microstructure of materials using SEM, XRD, and AFM. | |||||||||
| EAM3091 | Experiments of Semiconductor Processing | 3 | 6 | Major | Bachelor | 4 | English | Yes | |
| This course aims to provide opportunities for students enrolled in the School of Materials Science and Engineering to learn semiconductor processes, such as thin film deposition, etching, and lithography, and manufacture basic devices to get experiences on basic process flow of semiconductors. | |||||||||
| EAM3092 | Engineering for Rechargeable Batteries | 3 | 6 | Major | Bachelor | 4 | Korean | Yes | |
| The development of electric vehicles and energy storage devices is expected to accelerate the growth of the lithium ion secondary battery industry. The rapid development of Korean battery engineering society has made it the world's leading battery producing country, but China and Japan are competing it. We aim to concentrate in Materials Science and Engineering for understanding lithium ion secondary batteries, as well as the materials and production processes. Furthermore, electrochemical and structural analysis methods for lithium secondary batteries are systematically discussed. In addition, this class focuses on the structure and properties of lithium secondary battery core materials and their characteristics. | |||||||||
| EAM3093 | Introduction to Soft Matter Physics | 3 | 6 | Major | Bachelor | 3-4 | Korean | Yes | |
| Soft matter or soft condensed matter is a subfield of condensed matter, but is roughly distinguished from classical condensed matter that maintains pure solid properties such as metals and ceramics at room temperature or at a fairly high temperature. Soft matter includes liquids, colloids, polymers, foams, gels, liquid crystals, and a number of biological materials such as blood, muscle, milk, yogurt. Soft materials are very important in a wide range of applications, such as structural and packaging materials, foams and adhesives, detergents and cosmetics, paints, food additives, lubricants, rubber in tires. The development of the advanced soft materials is also highly desirable for the recently emerging foldable, wearable, and rollable flexible electronic devices applications. This class aims to introduce and understand the basic physics of the soft matter. These materials share an important common feature in that predominant physical behaviors occur at an energy scale comparable with room temperature thermal energy. That is, they are deformed or structurally altered by thermal or mechanical stress of the magnitude of thermal fluctuations. These properties have common physicochemical origins, such as a large number of internal degrees of freedom, weak interactions between structural elements, and a delicate balance between entropic and enthalpic contributions to the free energy. | |||||||||