For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| EME5938 | Mechanics of Elastoplasticity | 3 | 6 | Major | Master/Doctor | Mechanical Engineering | Korean | Yes | |
| This course covers the theory of elastoplasticity based on the continuum mechanics, and provides application examples for several materials. General stress and strain definitions are introduced for elastoplatsic range over onset of yield stress, in large deformation conditions. Students will study yield function, plastic potential, and hardening laws in order to analyze anisotropy and nonlinearity of material behaviors. Material dissipation caused by the plastic deformation is discussed with the entropy law and free energy theory. | |||||||||
| EME5942 | Additive manufacturing and its applications | 3 | 6 | Major | Master/Doctor | Mechanical Engineering | English | Yes | |
| The manufacturing industry has long optimized for traditional processes of mass production. Additive manufacturing (AM) is poised to dramatically alter the field through its ability to create complex geometries with new and custom material properties, often without the investment associated with traditional tooling startup costs. Design engineers must understand both the capabilities and limitations of additive processes in order to realize the products of the future. This course will explore and compare various additive processes while students design and build projects, considering how additive manufacturing can augment traditional subtractive and transformative processes. | |||||||||
| EME5943 | Modern Control System | 3 | 6 | Major | Master/Doctor | Mechanical Engineering | Korean | Yes | |
| This course is to study modern control theory for altering the dynamics of systems and managing their uncertainty. Key themes throughout the course will include linear versus nonlinear models, input/output response, system stability, state/output feedback, and robustness. This course will alow students to recognize control systems, to understand the principles of control theory, and to learn background for design and synthesis of control laws. | |||||||||
| EME5945 | Applied Nano Engineering | 3 | 6 | Major | Master/Doctor | Mechanical Engineering | English | Yes | |
| Applied Nano Engineering is a subject to understand the characteristics of nanostructures and explore examples of their application in various fields. To understand the principle that nanostructures show different characteristics from the existing bulk structures, and to understand how to manufacture large-area low-cost nanostructures, we aim to in-depth research into industrial technologies to which nanostructures are applied, such as energy devices and sensor devices. In particular, students will learn about the history, principles, and application cases of atomic force microscopy, which played a key role in the application of nanotechnology. | |||||||||
| EME5948 | Advanced materials and devices for energy storage and conversion | 3 | 6 | Major | Master/Doctor | 1-3 | Mechanical Engineering | - | No |
| This course deals with a subject regarding recent advanced nanomaterials of energy storage and conversion system for the graduate students. The first part covers the materials for energy storage using electrochemical devices (batteries and supercapacitors), extending to electric vehicles as future mobilities. Solar cells and photo-electrocatalysts for green energy conversion are also covered in the sencond part of this lectrue. | |||||||||
| ERC5001 | Global Collaboration Research | 3 | 6 | Major | Master/Doctor | Engineering | Korean | Yes | |
| This class aims to enhance global competence as a researcher who study innovative growth fields through overseas dispatch of graduate students. Student’s who are dispatched overseas and carrying out joint research in world university will learn - to establish global network for future research - to strive for the creation of new industries in the field of sustainable development and innovative growth of mankind - to grow into global innovative leader with the competence of ‘Value creation’, ‘Convergence’, ‘Innovation’, and ‘Collaboration’ through innovation in creative convergence experiences that which cross the intercultural, interdisciplinary and intergeneration. In this class, students are expected to focus on projects during the overseas dispatch period to improve the quality of their research. Each researcher will present final report after they complete dispatch study and will be given their credit based on the presentation. | |||||||||
| ERC7001 | Understanding and Utilizing the Metaverse Platform | 3 | 6 | Major | Bachelor/Master/Doctor | Engineering | Korean | Yes | |
| The main purpose of this course is training that equips students with metaverse-based business or service planning capabilities based on understanding of the technical elements consisting of the metaverse and hands-on experiences with major platforms and related devices. Opportunities to understand the characteristics and uses of each technical component, to study the cases of major services, and to identify strengths and weaknesses from the user's point of view through experience are given, and furthermore, the ability to derive creative ideas for the use and improvement of metaverse services is cultivated. do. | |||||||||
| ERC7002 | Understanding and Utilizing NFT | 3 | 6 | Major | Bachelor/Master/Doctor | Engineering | - | No | |
| The main purpose of this course is to educate students to have business or service planning skills using NFT based on understanding of the concept and underlying technology of NFT, related digital economic ecosystem, examples of NFT projects, and hands-on practice of NFT production and sales. It includes a basic understanding of blockchain and cryptocurrency, which are the base technologies of NFT, and digital art and digital assets, which are the major existing applications. Through learning about major project cases, legal considerations, market analysis tips, and technology trends, students will develop the ability to derive creative ideas for a wide range of future uses. | |||||||||
| ESC4003 | Quantum electronic device | 3 | 6 | Major | Bachelor/Master | 1-8 | Energy Science | Korean | Yes |
| Current Si technology keeps reducing the device scale to nm such that the quantum behavior of electron transport starts emerging. The quantum mechanical behaviors are routinely observed from various nanomaterials, with which many new devices have been proposed. The lecture covers the fundamental principles of quantum mechanics and its related transport behaviors. Then, quantum electronic devices that have been proposed and demonstrated will be introduced. The course requires pre-learning in physics, electronics, and material science in the level of 3rd and 4th grade. | |||||||||
| ESC5019 | Distinguished Lecture SeriesⅠ | 2 | 4 | Major | Master/Doctor | 1-8 | Energy Science | - | No |
| This course will be in the form of invited lectures by distinguished scholars of international reputation including Nobel Laureates. Distinguished domestic or foreign scholars in the fields of energy science and engineering will be invited. Students will discuss with the scholars after the lecture and submit reports. | |||||||||
| ESC5044 | Physical Bioscience for Energy | 3 | 6 | Major | Master/Doctor | 1-8 | Energy Science | - | No |
| Biological energy conversion has been explored for several years, in pursuit of cheap, environmental, renewable mass production of biofuel. This course covers biophysical chemistry as well as synthetic biology, genetic engineering, and system biology, etc. in terms of theoretical and practical approaches. This course will be beneficial to students due to interdisciplinary approaches. Also this topic will provide the graduate students with biophysics and physical biochemistry to enrich their research. The scope of this approach will reach into biofuel generation/hydrogen production/biomass reproduction. | |||||||||
| ESC5046 | Energy Device Characterization | 3 | 6 | Major | Master/Doctor | 1-8 | Energy Science | - | No |
| The lecture covers energy device related material characterization, optical, chemical, physical, and electrical property characterization in energy device fabrication process. Various device characterization methods including destructive and non-destructive analysis methods will be discussed for the fabrication completed energy device. Electrical property influencing factors will be treated to achieve the higher efficiency of energy device. | |||||||||
| ESC5103 | Solid State Principles for Energy | 3 | 6 | Major | Master/Doctor | 1-8 | Energy Science | Korean | Yes |
| Solid state physics is one of the fundamental methodologies for the understanding of physical processes concerning energy generation and storage inside the condensed matter. The description of physical phenomena using the band-theory and the quasi-particles (such as phonon or exciton) and that of physical interaction of metal/insulator/semiconductor with light, heat or mechanical force will be mainly reviewed in the class and it is expanded to the study about dielectrics, magnetism, and superconductivity. The energy generation such as photovoltaics/thermoelectrics and the energy storage using nanostructured materials will also be covered in the class. | |||||||||
| ESC5110 | Quantum Concepts for Energy | 3 | 6 | Major | Master/Doctor | 1-8 | Energy Science | English | Yes |
| This subject is planned to teach various background students the basic quantum mechanics for energy science. Energy science requires wide and deep knowledge on natural science such as physics and chemistry. Recent research trend, which is called as 'nano science', particularly emphasizes clear understanding of these basic science. However, students from engineering school such as electronic engineering, materials science, chemical engineering and mechanical engineering have difficulties in adopting and utilizing concepts of quantum mechanics for their in-depth study in laboratory. Professors in department of energy science ask their students proper and practical teaching of this subject. Quantum concepts for energy arose from Max Planck's solution in 1900 to the black-body radiation problem (reported in 1859) and Albert Einstein's 1905 paper which offered a quantum-based theory to explain the photoelectric effect (reported in 1887). The mathematical formulations of this subject are abstract. In this course, easy and straightforward mathematical approach will be adopted for non-physics major students. A mathematical function, the wave function, describes information about the probability amplitude of position, momentum, and other physical properties of a particle. Important applications of quantum mechanical theory include superconductors, LEDs and the laser, transistors and semiconductor, imaging devices such as MRI and electron microscopy et al. | |||||||||
| ESC5114 | Electromagnetism for Energy | 3 | 6 | Major | Master/Doctor | 1-8 | Energy Science | - | No |
| Electromagnetism provides the theoretical bases of energy materials, energy phenomena and energy applications. This course amis to learn and understand the basic concepts and mathematical comprehension of electromagnetism, of which contents cover vector algebra, electrostatics, magnetostatics, electromagnetic induction and Maxwell's equations. | |||||||||