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MSE501 Advanced Thin Film Technology (박막공학특론)
The need for thin films is now increasing as the electronic devices become small, light and integrated. In addition, fabrication of thin films from bulk materials is necessary to maximize their performance. Therefore, in this course we study the basic principles and techniques for the fabrication of thin films, the characterization methods and the applications of thin films.
MSE502 Nanoscale Surface Analysis (나노표면분석)
This course provides the fundamental principles of scanning tunneling microscopy (STM), scanning tunneling spectroscopy (STS), and related technique. The topic will also cover the application of STM and recent STM works on th nanoscale materials systems.
MSE505 Advanced Thermodynmaics of Materials (고급열역학)
This course is focused on the understanding of material properties and fundamental phenomena related to material processes. It covers phase equilibrium, calculation of heat capacitance, and the relation between free energy and phase diagram, etc.
MSE511 Nano Mechanics (나노역학)
This course covers mechanical behavior of materials at the nano-scale. While mechanical properties of materials have been known to be independent of size at the bulk-scale, mechanical behavior of materials at the nano-scale strongly depends on size. This course covers synthesis and characterization methods of nano-materials, and experimental approaches to measure and analyze mechanical behavior of materials at the nano-scale.
MSE512 Advanced Ferrous Metals and Alloys (철강소재특론)
This course aims to understand the microstructure and mechanical properties of ferrous metals and alloys, which are being used in a variety of industrial fields. The phase transformation phenomena we will cover in this course include TRIP and martensitic transformations. The relationship between microstructure and deformation behavior in the ferrous materials will also be discussed.
MSE531 Light Emitting Diodes (LED공학개론)
Technical progress in the field of light-emitting diodes has been breathtaking during the last few decades. State-of-the art LEDs are small, rugged, reliable, bright, and efficient. In contrast to many other light sources, LEDs have the potential of converting electricity to light with near-unity efficiency. This course will review the electrical and optical fundamentals of LEDs as well as advanced device structures. Recent technological breakthroughs and several application areas of LEDs including illumination and communication will also be discussed.
MSE550 Semiconductor Physics and Devices (반도체 물성과 소자)
This course is designed to provide professional understanding in the current (and future) device physics. The basics of semiconductor devices will be reviewed and the detailed phenomenological study on transistor, metal-semiconductor contact, PN junction, MOS capacitor, and JFET etc. will be offered.
MSE551 Surface and Interface Sciences (표면 및 계면과학)
This course concentrates on the surface property of solid matter, especially on metals and semiconductors. Various materials properties, such as physical, chemical, electrical and mechanical properties depend on the surface phase and its treatment. These novel properties of surfaces can be used to develop structural and functional materials.
MSE552 Characterization, Microstructure and Anisotropy of Materials (재료의 집합조직 및 이방성)
The purpose of this course is to mainly acquaint the student with texture, microstructure and anisotropy of aggregates of crystalline solids, i.e., polycrystals. The specific areas of learning include the mathematical basis for crystallographic (preferred) orientation (pole figures, inverse pole figures, ODF, and etc), grain boundary anisotropy (interface texture by misorientation distribution and grain boundary character/energy distributions), texture measuring methods (EBSD and X-ray), the effect of texture on elastic and plastic anisotropy in polycrystals, and image analysis and extraction of 3D information.
MSE553 Electrochemical methods: fundamental science and applications (전기화학법: 기초과학 및 응용)
The fields of electrochemistry and electroanalytical chemistry have evolved substantially in this few decades. The understanding of the fundamental sciences played crucial roles in wide electrochemical research and advanced technology development. This course is designed to provide fundamental electrochemistry and introduce various electrochemical processes and methods. Basic principles of physics and chemistry, overview of electrode processes, thermodynamics, charge transfers and interfacial reactions will be covered and discussed.
MSE571 Organic Optoelectric Materials and Devices (유기광전자재료 및 디바이스)
This course will provide the characteristics of electro-optic organic materials, such as conjugated polymers, liquid crystals, and devices will be reviewed and discussed. Their applications for organic optoelectronics such as organic LEDs, solar cells and laser diodes will be explained.
MSE572 Carbon Nano Materials (탄소나노소재특론)
This course will deal with the thermal, mechanical, physical, electronic, chemical properties of carbon nano materials such as fullerene, nanotube, graphene and so on. The related applications and analysis of carbon allotropes will also be covered.
MSE580 Polymer Structures and Properties (고분자구조 및 물성)
This course presents the physical properties of polymers, such as the chain confirmation, fluctuation, entanglements, etc. The macroscopic properties of polymeric materials are dramatically influenced by these changes in their microscopic state. Macromolecules beyond the simple polymers such as membranes, gels, polyelectrolytes and biopolymers and the formation of block copolymer nanostructures will also be studied.
MSE590 The Seminars (세미나)
The purpose of this course is to extend knowledge of the state-of-the-art R&D in real scientific fields; and to get indirect experience by contacting experts in various fields. Students and professors can exchange their own ideas and information to reach creative and fine-tuned achievements through the Seminars.
MSE601 Synchrotron Radiation (방사광가속기 응용)
This course is intended to provide an introduction to the physics and applications of synchrotron radiation. The relevant basic principles such as radiation, scattering, wave propagation, diffraction, and coherence will be reviewed and a broad range of phenomena and applications of synchrotron radiation including soft x-ray microscopy, spectromicroscopy, and soft x-ray laser will be covered.
MSE611 Advanced Light Metals and Alloys (경량금속소재특론)
This course aims to understand the microstructure and mechanical properties of light metals and alloys, which include aluminum, magnesium, titanium, and their alloys. Solidification, recrystallization, and precipitation phenomena will be covered in this course. The relationship between microstructure and deformation behavior in the non-ferrous materials will also be discussed.
MSE612 Alloy Design (합금설계)
This class will cover the theoretical fundamentals of metallic alloy design, utilization methods of thermodynamic database and commercial softwares, alloy fabrication, and characterization of the microstructure and mechanical properties of designed alloys.
MSE631 Electronic Properties of Materials (재료의 전자기적성질)
This class discusses the origin of electrical, magnetic and optical properties of materials, with a focus on the acquisition of quantum mechanical tools. It begins with an analysis of the properties of materials, presentation of the postulates of quantum mechanics, and close examination of the hydrogen atom, simple molecules and bonds. The course continues with the free electron model, elemental kinetic theory of thermal and electrical transport, band theory, and semiconductor physics and its applications.
MSE690 Master's Research (석사논문연구)
This course is related to the students graduate thesis and dissertation. As such, students should be actively working in a laboratory setting and gaining experience through hands-on experimentation.
MSE711 Advanced Metallic Materials (금속신소재특론)
This course deals with metallic materials widely studied recently in materials science and engineering and further expands to the understanding of relationships of processing, properties and mechanisms. While conventional metallic materials focus on structural materials at bulk scale, more discussion is placed on various metallic materials at multi-scales with various applications.
MSE731 Advanced Magnetic Materials (자성재료특론)
The study of magnetism and its intricacy with electricity runs in parallel with the technological drive to find new functional materials and their applications to the electronics, such as spintronics. This course aims to provide review of microscopic and macroscopic properties magnetic materials and the subjects of intense research activities in magnetism. Topics include isolated magnetic moments, environmental effects, their mutual interactions which lead to phase transitions, Further discussion on order and broken symmetry will be provided. The class will also review intense modern research areas, such as spintronics and nanomagnetism.
MSE732 Advanced Electric Ceramics (전자세라믹스특론)
This course will offer the basic understanding on dielectric properties of current transport mechanisms in thin insulating films which is (or will be) used in semiconductor memory and logic devices. The basics of memory devices will be reviewed and the detailed phenomenological study on the dielectric properties and leakage current properties of high-dielectric thin film will be offered.
MSE753 Nano Convergent Energy Devices (나노융합에너지소자특론)
This course provides the fundamental understandings of optoelectronic properties of nanomaterial. The energy related topics of nanomaterials such as LED, fuel cell, solar cell will be discussed in this lecture.
MSE754 Advanced Semiconductor Devices (고급반도체소자론)
This class will cover basic operation principles of Si or compound semiconductor devices including field-effect transistor, light-emitting diode, laser diode, solar cell, and nanoelectronics. Especially, this class will help graduate students grasp state-of-the-art research trends through case study and invited talks on specific semiconductor devices.
MSE771 Special Topics on Flexible Electronic Materials (플렉시블 전자소재특론)
Low cost roll-to-roll manufacturing process for flexible electronics and other applications are increasingly drawing attention as emerging technology platform for device fabrication. This course covers fundamental understanding of flexible conductive and semiconductor materials and their device applications to organic light-emitting devices, organic solar cells and organic thin film transistors. Further discussion on deposition processes, interfacial engineering and functional coatings will be discussed. The course will also go over the patterning techniques such as embossing and self-aligned imprint lithography, transfer technologies, digital fabrication, and printed electronics.
MSE801 Special Topics on Materials Science EngineeringⅠ (신소재공학특론Ⅰ)
This course covers cutting-edge technologies with applications in materials science and engineering, especially on advanced structural materials, multifunctional metallic composites, characterizations of materials at the nano-scale. This content is changeable depending on instructor.
MSE802 Special Topics on Materials Science EngineeringⅡ (신소재공학특론Ⅱ)
This course covers cutting-edge technologies with applications in materials science and engineering, especially on polymer nanocomposites, electronics, spintronics, and organic/inorganic optical materials. This content is changeable depending on instructor.
MSE803 Special Topics on Materials Science Engineering Ⅲ (신소재공학특론Ⅲ)
This course covers cutting-edge technologies with applications in materials science and engineering, especially on graphene, low-dimensional crystals, optoelectronic materials, and nano devices. This content is changeable depending on instructor.
MSE804 Special Topics on Materials Science Engineering Ⅳ (신소재공학특론 Ⅳ)
This course covers cutting-edge technologies with applications in materials science and engineering, especially on graphene, low-dimensional crystals, optoelectronic materials, and nano devices. This content is changeable depending on instructor.
MSE805 Special Topics on Materials Science Engineering Ⅴ (신소재공학특론 Ⅴ)
This course covers cutting-edge technologies with applications in materials science and engineering, especially on graphene, low-dimensional crystals, optoelectronic materials, and nano devices. This content is changeable depending on instructor.
MSE806 Special Topics on Materials Science Engineering Ⅵ (신소재공학특론 Ⅵ)
This course covers cutting-edge technologies with applications in materials science and engineering, especially on graphene, low-dimensional crystals, optoelectronic materials, and nano devices. This content is changeable depending on instructor.
MSE807 Special Topics on Materials Science Engineering Ⅶ (신소재공학특론 Ⅶ)
This course covers cutting-edge technologies with applications in materials science and engineering, especially on graphene, low-dimensional crystals, optoelectronic materials, and nano devices. This content is changeable depending on instructor.
MSE808 Special Topics on Materials Science Engineering ⅦI (신소재공학특론 ⅦI)
This course covers cutting-edge technologies with applications in materials science and engineering, especially on graphene, low-dimensional crystals, optoelectronic materials, and nano devices. This content is changeable depending on instructor.
MSE809 Advanced Semiconductor Devices (고급반도체소자론)
This class will cover basic operation principles of Si and compound semiconductor devices including field-effect transistor, light-emitting diode, laser diode, solar cell, and nanoelectronics. Especially, this class will help graduate students grasp state-of-the-art research trends through case study and invited talks on specific semiconductor devices.
MSE851 Advanced Transmission Electron Microscopy (전자현미경특론)
The need for micro- and nano-structure characterizations is now increasing as both the structural and electronic materials become smaller and smaller. In this course we study the advanced principles and techniques for modern transmission electron microscopy including 1) Imaging theory and experiments in high resolution electron microscopy, 2) Nano-diffraction and convergent beam electron diffraction, 3) X-ray energy dispersive spectroscopy, 4) electron energy loss spectroscopy and 5) simulations etc. Details of this lecture may be modified later.
MSE852 Quantum Analysis and Modeling (양자해석 및 설계)
In this course, we will discuss quantum calculation methods such as DFT and HF. To understand the characteristics of nanomaterials using quantum simulations, the theoretical backgrounds and the basic concept of algorithm will be introduced. Some basic explanation of quantum physics and solid-state physics will be briefly introduced for engineers who are not familiar with quantum mechanics.
MSE890 Doctoral Research (박사논문연구)
This course is related with the students graduate thesis and dissertation. As such, students should be actively working in a laboratory setting and gaining experience through hands-on experimentation.