Courses
COURSE FOR SOPHOMORE
| Class Code | Class Title | Point | |
|---|---|---|---|
| AMSE 201 | Physical Chemistry I | 3 | This course offers basic understanding of physical chemistry related to the materials science and engineering. The lecture covers the fundamental thermodynamics theory, phase transformation, and the kinetics of chemical reaction. |
| AMSE 202 | Physical Chemistry II | 3 | This course covers quantum mechanics and solid state physics as the fundamentals of the electrical and magnetic properties of materials in materials science and engineering in detail. |
| AMSE 203 | Introduction to Nano Materials | 3 | This course covers the various nano effects. The new electronic devices, catalysts, structural materials and composite materials using nano structure such as nano powder, nanotube, and nanowire will be treated. |
| AMSE 204 | Electronic and Magnetic Properties of Materials | 3 | As the continuing course of Materials Engineering I, it aims students to accumulate the knowledge on materials science and engineering which are the bases for major courses, by exercising the following topics with the theories and principles of materials science: mechanical properties, deformation of amorphous materials, electrons and electronic transport, electrical properties of junctions, and magnetic, electrical, optical properties of materials. |
| AMSE 205 | Structural Properties of Materials | 3 | This course offers the fundamental aspects of materials science and engineering such as the structure of solid, defect structure, phase equilibrium and the kinetics of phase transformation. |
| AMSE 207 | Introduction to Energy/Environment Materials | 3 | This course covers the various energy/environment materials. The working principles of fuel cell, solar cell, secondary battery, supercapacitor, environmental catalyst and environmental gas sensors will be treated and the relating materials issues will be studied. |
| AMSE 208 | Introduction to Physical Organic Materials | 3 | This class deals with the structure and basic characteristics of organic materials including polymers. This class covers the relationship between structural characteristics and properties, unique properties and basic characteristics of organic high molecular weight materials |
| AMSE 211 | Introduction to Ceramics | 3 | This course covers the introduction to the microstructure, properties, processing and applications of advanced ceramics. Various properties and their relationship to microstructure and crystal structure is emphasized. Comparison with other materials is also introduced. |
| AMSE 212 | Advanced Materials I | 3 | Lecture on the principles of the description of crystals, structure determination, plastic deformation, dislocations, vacancies, diffusion, nucleation, and recrystallization. |
| AMSE 214 | Metallic Materials and Their Application | 3 | Metal fabrication processes; relationship to structure and properties; properties of ferrous and nonferrous alloys for certain specific applications. |
| AMSE 215 | Engineering Design and Presentation | 1 | In order to learn the methology to solve typical engineering problems of research and industry environment, student will experience the overall engineering process, including planning, designing, prototyping and testing as a team and will make the presentation about the result of their team work. |
| AMSE 216 | Introduction to Biomaterials | 3 | Students learn the basic principles and types of metals, ceramics, and polymers that are applied as biomedical materials. In addition, students learn the manufacturing method and various applications of each biomedical material, orthopedic surgery, dentistry, cardiovascular, and artificial organs. Students will also acquire knowledge about nano biosensors using nanomaterials. |
| AMSE 217 | Organic Materials Chemistry | 3 | This course cultivates basic knowledge of organic chemistry necessary to understand organic materials, and deals with the nomenclature of organic chemicals, properties, reactions, and synthesis of simple small molecules. |
COURSE FOR JUNIOR
| Class Code | Class Title | Point | |
|---|---|---|---|
| AMSE 301 | X-ray crystallography | 3 | Lectures on crystallography(symmetry elements, classification of crystals, lattices, reciprocal lattices, and projection of crystals), physics of X-rays(production, detection, diffraction, and absorption), and scattering of X-rays(by an electron, an atom and a small crystal) will be given together with practices of various experimental methods in this course. |
| AMSE 303 | Electronics and Semiconductor Science & Engineering | 3 | The main purpose of this lecture is to teach the electronic properties of materials. First, the basic concept of the electron and lattice vibration will be introduced. The conduction of electron will be taught using the classical free electron model. The electron will be described in terms of wave and the energy band will be taught. Finally, the dielectric property of the materials will be taught. |
| AMSE 304 | Experimental Course in Materials Engineering II | 1 | The relations between electronics structure and electromagnetic and optical properties of materials obtained from experiments are analyzed to understand theoretical background. |
| AMSE 305 | Experimental Course in Materials Engineering I | 1 | The relations between microstructure and mechanical and thermal properties of materials obtained from experiments are analyzed to understand theoretical background. |
| AMSE 307 | Physical Metallurgy II | 3 | This course deals with basic knowledge of material properties related to the development of new materials such as solidification of materials, nucleation and growth, precipitation, diffusion and diffusion phase transformation, and non-diffusion phase transformation. |
| AMSE 308 | Solidification and Crystal Growth | 3 | Study the various solidification phenomena that occur during the solidification of liquid metal. Students study nucleation, interfacial stability, segregation, and crystal growth mechanism of pure metals and alloys, and also study single crystal growth and solidification-related provisions based on solidification theory. |
| AMSE 312 | Semiconducting Materials | 3 | This course covers the synthesis, properties, and applications of nanocermics. Research backgrounds and potential applications of advanced nanoceramics are introduced. |
| AMSE 313 | Properties of polymer materials | 3 | This class deals with general properties of organic electrical and electronics materials. Major topics are mechanical properties, thermal properties, viscoelastic properties, and elastic properties of organic electronics materials. |
| AMSE 315 | Thermodynamics of Materials | 3 | A study on fundamental concepts on phase equilibria and phase diagrams of materials based on thermodynamics. This course also covers the thermodynamical analysis of material microstructure such as defects. |
| AMSE 316 | Electronic Ceramics | 3 | Study the electrical characteristics of ceramics and review the various applications using electroceramics such as thermistor, varistor, sensor, and passive chip components. This course focuses the correlation between the principle and applications of a device. |
| AMSE 318 | Phase Equilibria | 3 | This course deals with the basic theories of thermodynamics related to phase equilibrium such as equilibrium conditions, and understands thermodynamic/physical phenomena from the equilibrium diagrams of 1, 2, and 3 component systems. It also understands the correlation between the microstructure and equilibrium of a material. |
| AMSE 324 | Characterization of Polymers | 3 | Students will study the basics and principles of using equipment and devices for processing physical and chemical properties of polymer materials, and conduct simple exercises together. The analyzers are DSC, Rheometer, FT-IR, Photoluminescence, Viscometer, Dielectric analyser, 2-roll mill, Extruder, etc. |
| AMSE 326 | Thin Film Science and Engineering | 3 | Thin films are a key material in modern electronic, optical, and magnetic technologies and various coating industries. This course explores a series of thin film process principles and thin film science knowledge such as patterning, oxidation, diffusion, deposition, wiring, and MEMS for semiconductor and device manufacturing. |
| AMSE 328 | Materials for Information Display | 3 | This course covers information display materials for LCD, PDP, and organic EL. In particular, we focus on TFT-LCD, which is thinner, lighter, and lower power consumption as compared with CRT. Materials technology for TFT-LCD, e.g., liquid crystal, color filter, packaging issue, back-light, glass substrates, are introduced. In addition, the development and the future prospect of display technology in monitor, flat-panel TV, and notebook computer, are described. |
| AMSE 331 | Deformation of Metals | 3 | Learn the relationship between stress and strain in elasticity and plastic deformation, learn the types of plastic processing methods of materials, and learn how to calculate the forces required when using these processing methods, the advantages and disadvantages of each processing method, and their effects on material properties. |
| AMSE 332 | Pyrometallurgy of metals | 3 | We study the dry smelting process of non-ferrous metals, including steel, which is the most important metal material for mankind, with theory. In particular, lectures on raw materials, smelting, refining, and agglomeration processes, along with physical and chemical principles, are based on Korea's steel smelting process, which employs advanced vacuum methods. |
| AMSE 333 | Structure and Properties of Metals and Alloys | 3 | This course deals with the basic concepts of the manufacturing process of metal materials, the relationship between structure and properties, and then deals with the characteristic properties and uses of various steel and non-ferrous metal materials. |
| AMSE 334 | Solid State Physics | 3 | This course deals with the relationship between the structure of electrons and atoms in solids and the thermal and optical properties of solids, and deals with semiconductor theory, applications, and electromagnetic properties of materials. |
| AMSE 336 | Heat Transfer and Diffusion | 3 | Students will study the theory of energy and mass transfer and the solution of the heat conduction equation and diffusion equation. Students learn basic knowledge to understand various micro-structure changes in materials from the viewpoints of heat transfer and material diffusion. |
| AMSE 337 | Mechanical Properties of Materials | 3 | Learn about the mechanical properties of materials and their relationship to the factors that govern them. The main lecture contents are as follows. Stress-strain relationship, Hooke's law, experimental measurement of stress/strain, stress transformation and main stress, main stress analysis in a simple structure, potential and generated energy, metal strengthening mechanism. |
| AMSE 371 | Research Trends in Materials Science and Engineering | 3 | Conduct a review of the latest research trends in the field of new materials engineering, and based on this, understand the correlation between the major deepening process and the field of new materials engineering in a detailed manner. It aims to understand the parts and materials used in the nano/bio field and the latest research trends. |
| AMSE 385 | Materials Capstone Design I | 3 | Based on the engineering theory, it recognizes engineering problems related to material development, selection, manufacturing process, and physical property measurement, and performs comprehensive design to solve them. Through this course, not only material design competency but also teamwork and communication competency are encouraged. |
| AMSE 386 | Materials Capstone Design II | 3 | Based on the engineering theory, it recognizes engineering problems related to material development, selection, manufacturing process, and physical property measurement, and performs comprehensive design to solve them. Through this course, not only material design competency but also teamwork and communication competency are encouraged. |
| AMSE 388 | Composite Materials | 3 | Students learn about the process and properties of composite materials manufactured using metal, ceramic, and polymer materials, analyze the role in the system for high-performance composite materials currently in use, and use them to synthesize new material composite materials. Study about. |
| AMSE 389 | Field Training I | 3 | By directly participating in industrial or R&D sites, it provides an opportunity to apply the theory and practical skills learned in the undergraduate course and acquire living knowledge. |
| AMSE 399 | Field Training II | 3 | By directly participating in industrial or R&D sites, it provides an opportunity to apply the theory and practical skills learned in the undergraduate course and acquire living knowledge. |
COURSE FOR SENIOR
| Class Code | Class Title | Point | |
|---|---|---|---|
| AMSE 403 | Electronic Polymers | 3 | This course introduces the technological trends of high-molecular electronic materials for semiconductor packages, and studies the molecular structure of thermosetting resins, which are mainly used for this, the relationship between the properties, and structural characteristics of electronic materials. |
| AMSE 406 | Electronic Properties of Organic Materials | 3 | It deals with basic principles and properties of electrical and electronic properties of organic electronic and electrical materials. In particular, it refers to the correlation between structural properties and electrical and electronic properties, measurement methods and principles, and phenomena seen when a voltage is applied to an organic electrical and electronic material. |
| AMSE 410 | Applied Electrochemistry | Principle of extraction of metal values from aqueous solution, introduction to leaching of ores and metal scraps, precipitation reactions, ionic exchange, solvent extraction and hydrometallugical processes of Zn, Al, Au, Ag, Cu, Ni, W, U and rare metal etc. | |
| AMSE 412 | Materials Design and Computer Control of Instrument | 3 | This course offers basic understanding of the interface between computer and instruments, the architecture of interface, and the algorithm for the remote control of instrument. The focus will be placed upon the improvement of the student's ability to design and characterize the materials through the practice of measurement computerization. |
| AMSE 414 | Ceramic Processing | 3 | This course covers fundamental principles and processing techniques for ceramic processing. Intelligent capacity for fabrication of ceramic component and processing improvement will be built from the understanding ceramic processing. |
| AMSE 415 | Semiconductor Processing | 3 | This course reviews the VLSI fabrication principles. |
| AMSE 416 | Field Experience in Materials Engineering II | 3 | Through this course, students learn how to use their knowledge on ceramics, metal and polymer to produce the real products. |
| AMSE 417 | Polymer Processing | 3 | Lectures on the effects of polymer properties such as molecular weight, viscosity and glass transition temperature on polymer processing. The course includes the analytic methods of those effects and the applications. |
| AMSE 419 | Emerging and Interdisciplinary Studies in Materials | 3 | The course provides an introduction to the most recent advances in the synthesis, lithographic patterning and characterization of nano-materials and to their physical and electronic properties. The materials presented will include semiconductor and metal nanoparticles and nano-wires, carbon fullerenes and nanotubes, organic nanoparticles and etc. Discusses the working principles of nanotechnology (NT) based devices such as nano-transistors and nano-sensors for information technology (IT) and biotechnology (BT) applications. |
| AMSE 421 | Field Experience in Materials Engineering I | 3 | Through this course, students learn how to use their knowledge on ceramics, metal and polymer to produce the real products. |
| AMSE 423 | Experimental Course in Materials Engineering III | 1 | Pick one specific research topic among various material science related topics researched by faculty member of MSE department and proceed the series of experiments for a semester. Then submit the result of experiment as the form of research article. |
| AMSE 427 | Introduction to Magentic Materials | 3 | Based on magnetic phenomena such as basic electromagnetic theory, paramagnetism, ferromagnetic magnetism, magnetic anisotropy, magnetic strain, magnetic domain theory and magnetic domain structure, it deals with the characteristics and applications of various magnetic materials. |
| AMSE 429 | Electromagnetism | 3 | Understanding and considering the Mexwell equation that understands the basic concepts and principles of electromagnetic phenomena, such as the interaction between electricity and magnetism, and uses them concretely and theoretically describes that electricity and magnetism are not separated from each other but are closely related to each other. It focuses on helping students to understand quickly by using an application-oriented learning method that can be used in an exciting and practical field required for new material engineering. |
| AMSE 434 | Introduction to Superconducting Materials and Applications | 3 | Superconductivity theory, basic principles, characteristics, synthesis, and application through various and comprehensive lectures and experiments/practices to induce interest in superconducting materials and applications, and further to understand superconductivity as the next-generation cutting-edge application technology, specializing in the field of superconductivity The goal is to train people. This course includes an experimental process to create superconductivity by designing various parameters required to synthesize YBCO superconductor, which is a high-temperature superconductor. |
| AMSE 436 | Electronic Material Processing | 3 | Students learn about the effects of electronic material synthesis and application techniques applied in powder form, composition, shape and particle size of materials on the properties of electronic materials. The principles and techniques for synthesizing functional electronic ceramics, metal and glass electronic materials by gas phase processes are also introduced. |
| AMSE 437 | Organic Nanomaterials | 3 | Within the scope of basic materials science and chemistry, this course teaches the basic principles of the structure and bonding of organic molecules and the interaction of organic molecules. Based on this understanding, this course introduces how organic molecules are assembled into various nanostructures. This course briefly introduces how organic nanomaterials are applied as bio applications. |
| AMSE 438 | Applications and Properties in Electronic Materials | 3 | Students learn about various electronic material application devices such as semiconductor devices, solid-state optical devices, superconductors, sensors, and actuators. This course focuses on the correlation between device operation principle and application range. This lecture examines PN junction, FET, LED, display (LCD, OLED, PDP, FED), solar cell, thermistor, sensor, actuator, etc. |
| AMSE 441 | Industry-University Cooperative Lecture I | 3 | The purpose of this course is to acquire applied knowledge required for actual industrial sites through industry experts such as CEO and CTO. |
| AMSE 443 | Optical Materials and Devices | 3 | This course aims to understand the material properties of optical semiconductors for optical devices and the properties of applied devices. To this end, the electrical properties, optical properties, and structural properties of inorganic and organic optical semiconductor materials are systematically dealt with by doping, temperature, and composition changes affecting them. It also covers device operation principles and applications such as LED, LD, solar cells, and photodetector. |
| AMSE 461 | Capstone Design I | 3 | This course aims to develop the ability for students in the group to experience open problems and creatively solve them. Students understand recent research trends according to a given research theme, and conduct a literature search, research plan establishment, research capability improvement, research planning and technical report preparation through comprehensive design. |
| AMSE 462 | Capstone Design II | 3 | This course aims to develop the ability for students in the group to experience open problems and creatively solve them. Students understand recent research trends according to a given research theme, and conduct a literature search, research plan establishment, research capability improvement, research planning and technical report preparation through comprehensive design. |
| EGRN 103 | Creative Design | 1 | By educating students entering the College of Engineering, the concept of creativity and the process of creative thinking, and shaping and designing basic ideas derived based on creativity and making them with simple materials and tools, it is possible to develop interest in major subjects to be encountered in the future. Induce and learn the basic concepts necessary for comprehensive design. |