For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| ECE6006 | Doctor's Research Problem Ⅴ | 3 | 6 | Major | Doctor | 1-4 | - | No | |
| This course offers a directed and independent study for Ph.D degree students on the fourth level. Most subjects assigned to students are related to the Ph.D thesis topic for each student, which include literature survey, directed experiments, data analysis, and writing proposal. The aim of class is to provide various conceptual backgrounds for the research, current problem and research needs, experimental design, and analysis for the results, which may not be offered by regular classes in the graduate program. Grade is given by the research advisor of students based on subjective evaluation for discussion and/or written reports. | |||||||||
| ECE7001 | Semiconductor Device Simulation and Practice | 3 | 6 | Major | Bachelor/Master/Doctor | Korean | Yes | ||
| The primary goal is to describe the operating principles and device fabrication technology in electrical and electronic engineering. Lecture deals with an advanced method of material property characterization and device design (SILVACO simulation). Atlas with Spices 2B, 2D Device Simulation. Blaze, 2D Hetero junction Bipolar transistor, and III-V compound Simulator, Laser, 2D Semiconductor Laser Simulator, Giga, 2D Lattice Heating Simulator with Heat Sink, Mixed Mode, 2D Mixed Circuit and Device Simulator, TFT, 2D Amorphous and Poly Silicon Simulator, Luminous, 2D Optoelectronic Simulator, Quantum, 2D Quantum Effects Simulator, Ferro, 2D Ferroelectric Material Simulator. | |||||||||
| ECE7001 | Semiconductor Device Simulation and Practice | 3 | 6 | Major | Bachelor/Master/Doctor | Electrical and Computer Engineering | Korean | Yes | |
| The primary goal is to describe the operating principles and device fabrication technology in electrical and electronic engineering. Lecture deals with an advanced method of material property characterization and device design (SILVACO simulation). Atlas with Spices 2B, 2D Device Simulation. Blaze, 2D Hetero junction Bipolar transistor, and III-V compound Simulator, Laser, 2D Semiconductor Laser Simulator, Giga, 2D Lattice Heating Simulator with Heat Sink, Mixed Mode, 2D Mixed Circuit and Device Simulator, TFT, 2D Amorphous and Poly Silicon Simulator, Luminous, 2D Optoelectronic Simulator, Quantum, 2D Quantum Effects Simulator, Ferro, 2D Ferroelectric Material Simulator. | |||||||||
| ECH4001 | Advanced Instrumental Analysis | 3 | 6 | Major | Bachelor/Master |
3-4
1-4 |
Chemical Engineering | English | Yes |
| In this subject, general techniques, their principles and the informations of the material characterization will be discussed. The most useful techniques, such as, gas chromatography, liquid chromatography, nuclear magnetic resonance spectroscopy, infrared spectroscopy, UV-Vis spectroscopy, will be throughly discussed. | |||||||||
| ECH4002 | Experimental Design and Analysis | 3 | 6 | Major | Bachelor/Master |
3-4
1-4 |
Chemical Engineering | - | No |
| This course deals with the fundamentals of experiment design and data analysis methods. It covered the statistics for experiments and new methods for data analysis. | |||||||||
| ECH4003 | Advanced Chemical Reaction Engineering | 3 | 6 | Major | Bachelor/Master |
3-4
1-4 |
Chemical Engineering | English | Yes |
| Characteristics of real commercial reactors are examined. Analysis and design of homogeneous nonisothermal reactors, reactors with nonideal flow, noncatalytic heterogeneous reactors are dealt with. Effects of mass and heat transfer, solution of simultaneous material and energy balance equations, the concept of residence time distribution are introduced. This subject focuses on formulation and solution of equations for each type of reactors and discussion of the results, thereby enhancing the capability dealing with reactor analysis and design. | |||||||||
| ECH4004 | Interface Engineering | 3 | 6 | Major | Bachelor/Master |
3-4
1-4 |
Chemical Engineering | English | Yes |
| A course dealing with the principles and applications of colloidal and interfacial phenomena, examing topics such as capillarity of fluid-fluid interfaces, fluid-solid interfaces, electronic double layer theory, surfactants and dynamic phenomena at interfaces. | |||||||||
| ECH5005 | Advanced Catalyst Engineering | 3 | 6 | Major | Master/Doctor | 1-4 | Chemical Engineering | - | No |
| Catalysts are used in a majority portion of chemical processes. This subject introduces important catalytic processes and deals with basic concepts and theories of catalysis. Types of catalysts and catalytic reactions, principles of catalysis, catalytic reaction kinetics, catalytic reactors, catalyst preparations, catalyst characterizations, representative catalytic processes are dealt with. | |||||||||
| ECH5014 | Advanced Chemical Process Analysis | 3 | 6 | Major | Master/Doctor | 1-4 | Chemical Engineering | - | No |
| This course aims at proper formulation of chemicophysical processes into correct mathematical language and their solutions with valid interpretation. It covers problem formulation by elementary differential balances, solution including perturbation. | |||||||||
| ECH5015 | Special Topics in Energy Engineering | 3 | 6 | Major | Master/Doctor | 1-4 | Chemical Engineering | Korean | Yes |
| This course deals with the new trend in energy technology. It covered the new technology of energy production and energy transportation. It also covered the particularly new and renewable energy technology. | |||||||||
| ECH5017 | Advanced Nano - Processing Technology | 3 | 6 | Major | Master/Doctor | 1-4 | Chemical Engineering | - | No |
| Nano processing technologies required for various nano-devices are discussed. These include thin film deposition processes, patterning technologies, etching, self assembled monolayer (SAM), and carbon nanotube processing. Recent research and development trend are also discussed. | |||||||||
| ECH5023 | Advanced Electrochemistry | 3 | 6 | Major | Master/Doctor | 1-4 | Chemical Engineering | Korean | Yes |
| In this lecture, operation principles of batteries and electrochemical processes will be investigated based on the knowledge of thermodynamics and chemical reaction engineering. Performance evaluation techniques and experimental analysis tools for the electrochemical systems are also introduced. Furthermore, vision of the electrochemical processes and its application system will be discussed and the leading-edge technologies in electrochemical and battery industry are introduced. Especially, it will focus on the analytical techniques to evaluate the performance of electrochemical system and its application. | |||||||||
| ECH5028 | Functional and High Performance Polymers | 3 | 6 | Major | Master/Doctor | 1-4 | Chemical Engineering | English | Yes |
| This lecture focused on the important materials and new technologies of the polymer industry. Topics surveyed in the recent series of lecture were water-soluble polymers, biodegradable polymers, hydrogel and stimuli-sensitive polymers, polymeric biomaterials, polymers for electronics and display applications, polymer nanocomposites, high-temperature high-performance polymers and fibers. Their synthesis, physical properties, and application are discussed. | |||||||||
| ECH5029 | Special Topics in Composite Materials | 3 | 6 | Major | Master/Doctor | 1-4 | Chemical Engineering | Korean | Yes |
| In this class, the physical properties of composite materials composed of polymers and metal or ceramic materials. The methods for estimation of mechanical strength of composit materials will be carefully discussed with several examples. The mechanical properties, such as, toughness, aging process, impact resistance will be discussed. | |||||||||
| ECH5042 | Advanced Chemical Engineering Thermodynamics | 3 | 6 | Major | Master/Doctor | 1-4 | Chemical Engineering | English | Yes |
| For quantitative estimations of liquid-liquid and liquid-vapor equilibrium properties for mixtures, especially strong polar molecular mixtures, and solution of the problems of separation process and chemical process design, five-step approaching procedure will be given: 1.Use statistical thermodynamics 2.Apply molecular science theories 3.Derive physical models 4.Obtain model parameters from experimental measurements 5.Construct model to practice through a computer for engineering-design calculations. | |||||||||